S. No. No.: Physical Chemistry [PDF]
HANDBOOK OF CHEMISTRY S. No. CONTENTS Page No. PHYSICAL CHEMISTRY 1. 2. Some Basic Concepts of Chemistry Solutions
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HANDBOOK OF CHEMISTRY
S. No.
CONTENTS
Page No.
PHYSICAL CHEMISTRY 1. 2.
Some Basic Concepts of Chemistry Solutions
2-3 6-7
3.
Redox Reactions
10
4.
Electrochemistry
12-15
5. 6.
Behaviour of gases Atomic Structure
18-19 20-22
7.
Chemical Kinetics
24-25
8.
Thermodynamics & Energetics
28-31
9. 10.
Chemical Equilibrium Ionic Equilibrium
32-34 36-40
11.
Solid State
42-43
12.
Surface Chemistry
46-47
1.
INORGANIC CHEMISTRY Some Important Increasing order
50-52
2.
Periodic Table
53-57
3.
Chemical Bonding
60-69
4. 5.
s-Block elements p-Block elements
72-74 77-88
6.
Coordination Chemistry
90-93
7.
d-Block (Transition Elements)
94-97
8. 9.
Metallurgy Hydrogen
99-100 102-103 ORGANIC CHEMISTRY
E
1.
Table for IUPAC Nomenclature
2. 3.
Isomerism Reaction Mechanism
4.
Practical Organic Chemistry
5.
Distinction b/w pair of compound
116-119
6. 7.
Hydrocarbons Haloalkanes & Grignard Reagents
122-125 128-130
8.
Alcohol, Ether and Phenol
132-138
9.
Carboxylic Acid
10. 11.
Amines Organic Reagents
142-144 146-149
12.
Organic Name Reactions
150-152
13.
Polymers
14.
Carbohydrates
106 108-110 112 114
140
154 156-157
PHYSICAL CHEMISTRY
Chemistry HandBook
C HAP TE R
ALLEN
SOME BASIC CONCEPTS OF CHEMISTRY SOME USEFUL CONVERSION FACTORS 1 Å = 10–10 m, 1 nm =10–9 m 1 pm = 10–12 m 1 litre = 10–3 m3 = 1 dm3 1 atm = 760 mm or torr=101325 Pa or Nm–2
1 bar = 105 Nm–2 = 105 Pa 1 calorie = 4.184 J 1 electron volt (eV) = 1.6022 × 10–19 J (1 J = 10 ergs) 7
(1 cal > 1 J > 1 erg > 1 eV)
RELATIVE ATOMIC MASS OR RELATIVE MOLECULAR MASS Mass of one atom or molecule w.r.t. 1/12th of 12C atom C® 12 H2O ® 18 It is unitless
ATOMIC MASS OR MOLECULAR MASS Mass of one atom or molecule in a.m.u. C ® 12 amu H2O ® 18 amu
GRAMS ATOMIC MASS OR GRAM MOLECULAR MASS
ACTUAL MASS mass of one atom or molecule in grams C ® 12 × 1.66 × 10–24 g H2O ® 18 × 1.66 × 10–24 g
Mass of one mole of atom or molecule C® 12 g H2O ® 18 g It is also called molar weight
DEFINITION OF ONE MOLE One mole is a collection of that many entities as there are number of atoms exactly in 12 g of C-12 isotope.
1g 1u = 1 amu = (1/12)th of mass of 1 atom of C12 = N = 1.66 × 10-24 g A
For elements • 1 g atom = 1 mole of atoms = NA atoms • g atomic mass (GAM) = mass of NA atoms in g. • Mole of atoms =
Mass ( g ) GAM or molar mass
• 1 g molecule = 1 mole of molecule = NA molecule • g molecular mass (GMM) = mass of N A molecule in g. • Mole of molecule =
Mass ( g ) GMM or molar mass
1 mole of substance 23
Contains 6.022 × 10 particles Weight as much as molecular weight / atomic ionic / weight in grams If it is a gas, one mole occupies a volume of 22.4 L at 1 atm & 273 K
2
For ionic compounds
• 1 g formula unit = 1 mole of formula unit = NA formula unit. • g formula mass (GFM) = mass of N A formula unit in g. • Mole of formula unit =
Mass ( g ) GFM or molar mass
Average or mean molar mass The average molar mass of the different substance present in the container Mavg =
M1n1 + M2n2 + .... n1 + n2 + ....
Here M1, M2 are molar mass of substances and n1, n2 are mole of substances present in the container.
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For molecule
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Chemistry HandBook
CHAP TER
ALLEN
DENSITIES Mass Density = , unit : g/cc volume Relative Density =
VAPOUR DENSITY Ratio of density of vapour to the density of hydrogen at similar pressure and temperature.
Density of any substance Density of reference substance
* mass % of an element in a compound =
Vapour density =
Molar mass 2
atomicity of an element × atomic mass of an element ´ 100 molecular mass of compound
Molarity (M)
V(L)
V(L) mass in (g) W(g)
¸ molar mass × molar mass
¸ 22.4 L mol—1
Number of Moles (n)
NA
× 22.4 L mol
—1
Volume of gas (in L) at NTP/STP
NA
Number of Particles r STOICHIOMETRY BASED CONCEPT
r EQUIVALENT WEIGHT
[Concept of limiting reagent] aA + bB ®cC + dD • a,b,c,d, represents the ratios of moles, volumes [for gaseous] and molecules in which the reactants react or products formed. • a,b,c,d, does not represent the ratio of masses. r HOW TO FIND L.R.
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• Case I : If data of only one reactant is given then treat that reactant as L.R. and other reactants as excess reagent.
E
• Case-II : If data of more than one reactants are given then first convert all the data into moles then divide the moles of reactants with their respective stoichiometric coefficient. The reactant having minimum ratio will be L.R. then find the moles of product formed or excess reagent left by comparing it with L.R. through stoichiometric concept.
• Equivalent weight =
molar weight valency factor ( VF )
• V.F. for elements = Valency Ex.:
Na =1, Al=3, N2=6, O2 =4, H2=2
• V.F. for ionic compounds (salts) = total charge on cation / anion Ex. : Na2+1 CO3–2 ® V.F. = +1×2 = 2 K4+1[Fe(CN)6] = V.F. = +1× 4 = 4 • V.F. for acids = No. of replaceable H+ ions HCl =1, H2SO4= 2, H3PO4= 3 H3PO3=2, H3PO2 =1 • V.F. for bases = No. of replaceable OH– • NaOH =1, Ba(OH)2=2, Ca(OH)2=2, Al(OH)3=3
KEY POINTS
r r
Dulong & Petit’s law (only for solids (except Be, B, Si, C) Atomic mass × specific heat (in Cal/grams °C) » 6.4 Victor -Mayer’s method is used to determine molecular weight of volatile compound.
3
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4 ALLEN
IMPORTANT NOTES
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IMPORTANT NOTES
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Chemistry HandBook
C HAP TE R
ALLEN
SOLUTIONS =
Normality (N) No. of Gram Equivalents of solute Volume of solution (L)
=
Formality (F) Mass of solute (g)
=
Molarity (M) No. of moles of solute = Volume of solution (L)
Relation b/w M&N N=M× Valency factor
=
% by Mass (w/W) Mass of solute (g) × 100 Mass of solution (g)
Relation b/w m & X XB m×(M.wt)A = XA 1000
Strength of solution (S) Mass of solute (g) = Volume of solution(L)
PPM (by mass) Mass of solute(g) × 106 Mass of solution(g)
=
PPM (by volume) Volume of solute × 106 Volume of solution
PPM (by w/V) Mass of solute (g) = × 106 Volume of solution (mL)
COLLIGATIVE PROPERTY
Solid-Liquid System
Liquid: Volatile solvent (A) & volatile solute (B) P' A=XAPAo & P' B =XBPBo Ptotal = P'A+P'B=PoA XA + PoBXB o Ptotal = (P B -PoA)XB + PoA P'A=YAPT & PB'=YBPT
Solid : Non-volatile solute(B) & Liquid : volatile solvent (A) n A o o Ptotal=PA XA =n +n ×PA (QPBo=0) A B
(Dalton law for gaseous mixtures)
P'A=PAoXA = YAPT o P'B=P BXB=YBPT (YA & YB : mole fraction in vapour phase)
Raoult's law
PAo-PS =XB PAo Lowering of vapour pressure = DP = PAo-PS (RLVP)=
Derived from RLVP : o PA -PS nB nA PS
Depression in Freezing Point(DT f)
DTb=(Tb)solution - Tb = i×m×Kb Kb = molal elevation constant or ebullioscopic constant for a solvent
DTf=(T f)-(T f)solution = i×m×K f K f = molal depression constant or Cryosopic constant for a solvent
A -P S 0 PA
DPµ
i× nB nA
nB nA
Kf =
RTo2b ×M.wt) 1000 × DHvapour
Kb=
RTo2 b 1000 × Lvapour
ent solv tion solu
Po PS
DTb o
Osmotic Presure (p)
K f=
RTo2f ×M.wt) 1000 × DHfusion
RTo2 f 1000 × Lfusion
Kf=
Liquid solvent
Tb Tb Temperature/K
6
o
Osmosis : Net flow of solvent molecules from dilute solution to concentrated solution through semi-permeable membrane. p = hdg For dilute solution : p = i × CRT
* Isotonic solution : p1 = p2 (Primary condition) At constant T; C1 = C2 (secondary condition)
Vapour pressure
0
Vapour pressure
P
Observed colligative property Calculated colligative property Calculated Molar Mass Observed Molar Mass For i=1 : Neither Association nor Dissociation Eg. : Sugar, Glucose, Urea etc. Dissociation (i>1) i =1 + (n-1)a n=total no. of ions a=Degree of dissociation Association (i>1) i =1 - a+a/n n=No. of solute particles asso. a = Degree of Association
Elevation in Boiling Point (DTb) o
For dilute solution (nB (VP) calculated (BP)observe d < (BP) calculated (A–A) & (B–B)>(A–B) Vapour pressur e of solution
o
P2
x 1=0 x2=1
P P
P1
o 1
P2
x1=1 x1=1® x 2=0 ¬x1=1
mole fraction
DHmix > 0 DSmix > 0
NON-IDEAL SOLUTION NEGATIVE DERIVAT ION Do not Obey Raoult's Law (VP)obser ved < (VP) calcul ated (BP)observed > (BP) calculated (A-A)&(A–B) 0 DG < 0
of solution
O 2
Vapour pressure
IDEAL SOLUTION Obey Raoult's Law (VP)observed = (VP) calculated (BP)observed = (BP) calculated (A–A)=(A–B)=(B–B)
Vapour pressure
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Konowaloff's Rule : The vapour phase is richer in more volatile component than the less volatile component.
x1=0 x2=1
P P2
O 1
P1
mole fraction
DHmix0
x =1 x1=1® x 1 2=0 ¬x1=1
DVmix< 0 DG PR V
t
At high pressure, Vanderwaal's eqn is PVm - Pb = RT
t
At low pres. or Moderate pressure Vanderwaal's eqn is PVm +
a force of attraction liquification; b, effective size of molecule , incompressible vol ,
t
t
a = RT Vm
At very low pressure, high temp. a real gas behaves like an ideal gas. Gases having value of a; will have TC; rate of liquefaction.
compressible vol ¯ Compressibility factor (z) =
( Vm ) obs = P ( Vm ) obs Vi
RT
If z = 1, the gas show ideal gas behaviour. If z > 1, the gas show positive deviation. If z < 1, the gas show negative deviation.
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IMPORTANT NOTES
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Chemistry HandBook
CHAPTER
ALLEN
ATOMIC STRUCTURE IMPORTANT DEFINITIONS Proton (mP) /anode rays
Neutron (mn)
Electron(me) / cathode rays
mass =1.67 × 10–27 kg
mass = 1.67 × 10–27 kg
mass = 9.1 × 10–31 kg
mass = 1.67 × 10–24 g
mass = 1.67 × 10–24 g
mass = 9.1 × 10–28 g
mass = 1.00750 amu
mass = 1.00850 amu
mass = 0.000549 amu
e/m value is dependent on the nature of gas taken in discharge tube.
e/m of electron is found to be independent of nature of gas & electrode used.
ATOMIC MODELS
REPRESENTATION OF AN ELEMENTS 5
Atom ic num ber
A Z
X
S ym bol of the elem ent
5 5
Terms associated with elements : 5
Atomic Number (Z) : = No. of protons Electron = Z – C (charge on atom)
5
5
5
The volume of the nucleus is very small and is only a minute fraction of the total volume of the atom. Nucleus has a diameter of the order of 10 –13 cm and the atom has a diameter of the order of 10–8 cm.
5
Thus, diameter of the atom is 105 times to the diameter of the nucleus and volume of atom is 1015 times to volume of nucleus.
Mass number (A) =Total number of neutron and proton present A = Number of proton + Number of Neutrons Isotopes : Same atomic number but different mass number Ex. : 6C12, 6C13, 6C14
5
Isobars : Same mass number but different atomic number
ELECTROMAGNETIC SPECTRUM 5
RW ®MW ®IR ®Visible ®UV ®X-rays ®CR
Isodiaphers : Same difference in the number of neutrons & protons
5 5
(Radiowaves ®Microwaves ®Infrared rays ®Visible rays ®Ultraviolet rays ®X-rays ®Cosmic rays) Wavelength decreases ¾¾¾¾¾¾¾¾¾¾¾® Frequency and energy increases ¾¾¾¾¾¾¾®
Ex. 5B11, 6C13
5
• c=nl
Ex. 1H3, 2He3 5
5
Isotones : Having same number of neutrons Ex. 1H3, 2He4
5
Isosters: They are the molecules which have the same number of atoms & electrons Ex. CO2, N2O
5
Isoelectronic:Species having same no. of electrons Ex. Cl–, Ar, S2–
20
Thomson : An atom considered to be positively charged sphere where e– is embedded inside it. Drawback : Cannot explain stability of an atom. Rutherford Model of an atoms : Electron is revolving around the nucleus in circular path. RN = R0(A)1/3, R0 = 1.33 × 10–13 cm [A mass number, RN = Radius of nucleus] SIZE OF NUCLEUS
•T =
1 n
• l= •E =
c n
•n =
1 n = l c
hc = hn , h = 6.626 × 10–34 Js l
12400 eV •E = l (Å)
•Total amount of energy transmitted E = nhn = n = number of photons
nhc l
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M ass num ber
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Chemistry HandBook
CH APTER
ALLEN
HYDROGEN SPECTRUM
BOHR’S ATOMIC MODEL Theory based on quantum theory of radiation and the classical laws of physics
K ( Ze) ( e) mv2 = • r r2 nh • mvr = or mvr = nh 2p • Electron remains in stationary orbit where it does not radiate its energy. • Radius : r = 0.529 ´
n2 Å Z
• Velocity : v = 2.188 ´ 106
Z -1 ms n
• Rydberg’s Equation :
1ù 1 é1 = n = RH ê 2 - 2 ú ´ Z2 l ë n1 n2 û
R H @ 109700 cm-1 = Rydberg constant
• For first line of a series n2 = n1 +1 • Limiting spectral line (series limit) means n2 = ¥ • Ha line means n2 =n+1; also known as line of longest l, shortest n, least energy • Similarly Hb line means n2 = n1 +2 • When electrons de-excite from higher energy level (n) to ground state in atomic sample, then number of n ( n - 1) 2 • When electrons de-excite from higher energy level (n2) to lower energy level (n1) in atomic sample, then number of spectral line observed in the spectrum
Z2 •Total energy (KE + PE) = –13.6 × 2 eV/atom n
spectral lines observed in the spectrum =
KZe2 - KZe2 KZe2 , PE = , KE = 2r r 2r PE = –2KE, KE = –TE, PE = 2TE v • Revolutions per sec = 2pr
• TE = -
=
( n2 - n1 )( n2 - n1 + 1)
2 • No. of spectral lines in a particular series = n2 – n1
2pr v • Energy difference between n1 and n2 energy level
• Time for one revolution =
Hydrogen
1 ö eV 1 ö æ 1 æ 1 DE = E n2 - E n1 = 13.6 ´ Z2 ç 2 - 2 ÷ = IE ´ ç 2 - 2 ÷ è n1 n2 ø atom è n1 n2 ø
where IE = ionization energy of single electron species. • Ionization energy = E¥ - EG.S. = 0 - EG.S. EG.S.= Energy of electron in ground state
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n=1
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Spectrum
Lyman ® Any higher orbit ® 1 [Found in U.V. region]
Pfund
® Any higher orbit ® 5 [Found in I.R. region]
4
5
3
L
M
N
O
E1
< E2
< E3
< E4
E3–E2 >
E4–E3 >
E5–E4 >
10.2
1.89
0.66
0.31 eV
Å
(n1)
Balmer ® Any higher orbit ® 2 [Found in Visible region] Paschen ® Any higher orbit ® 3 [Found in I.R. region] Brackett ® Any higher orbit ® 4 [Found in I.R. region]
2
K
(n2)
–0.85 –0.54 eV
12.1 12.75 13.06
KEÅ PEQ TEQ st Ground I E.S 2ndE.S State (Excited State)
3rdE.S
At n = ¥ is 0 At n = ¥ is 0 At n = ¥ is 0
4thE.S
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Chemistry HandBook
CHAPTER
de-BROGLIE HYPOTHESIS • • •
• •
ALLEN
HEISENBERG UNCERTAINITY PRINCIPLE
All material particles posses wave character as well as particle character. h h l= = mn p The circumference of the nth orbit is equal to n times of wavelength of electron i.e., 2prn = nl Number of waves = n = principal quantum number 150 Å Wavelength of electron ( l ) @ V ( volts ) h l= 2mKE
•
•
•
According to this principle, “ it is impossible to measure simultaneously the position and momentum of a microscopic particle with absolute accuracy” If one of them is measured with greater accuracy, the other becomes less accurate. h h or ( Dx ) ( Dv ) ³ 4p 4pm where Dx =Uncertainity in position Dp = Uncertainity in momentum Dv = Uncertainity in velocity m = mass of microscopic particle Heisenberg replaced the concept of orbit by that of orbital. Dx.Dp ³
QUANTUM NUMBER
In an atom each shell, subshell, orbital and electron are designated by a set of 4 quantum numbers. Principal quantum number (By Bohr) Þ Indicates = Size and energy of the shell, distance of e– from nucleus Þ Values n = 1, 2, 3, 4, 5..................... h Þ Angular momentum = n ´ 2p Þ Total number of e–s in a shell = 2n2 Þ Total number of orbitals in a shell = n2 Þ Total number of subshell in a shell = n
5
Azimuthal/Secondary/Subsidiary/Angular momentum quantum number (l) Þ Given by = Sommerfeld Þ Indicates = Sub shells Þ Values Þ 0, 1..............(n–1) Þ Indicates shape of Sub shell Value Values of l Initial from of n [Shape] word eg. l = 0 (s) [Spherical] Sharp If n = 4 l=1 [p] [Dumb bell] Principal l=2 [d] [Double dumb bell] Diffused l=3 [f] [Complex] Fundamental Þ Total no. of e–s in a sub shell = 2(2l + 1) Þ Total no. of orbitals in a sub shell = (2l + 1) Þ Orbital angular momentum h = h l ( l + 1) = l ( l + 1) 2p h = Planck's constant
5 RULES FOR 5 FILLING OF 5 ORBITALS 5
22
Þ
For H & H- like species all the subshells of a shell have same energy. i.e. 2s = 2p 3s = 3p = 3d 5 Magnetic quantum number (m) Þ Given by Linde Þ Indicates orientation of orbitals i.e. direction of electron density. Þ Value of m = –l .........0.........+l Þ Maximum no of e's in an orbital = 2 (with opposite spin) py pz m for p sub shell = p x –1 0 +1 m for d sub shell = dx y –2
5
dyz –1
d z2 0
dxz +1
d x 2– y 2 +2
Spin quantum number (ms or s) Given by Uhlenback & Goudsmit Values of s = ±½ Total value of spin in an atom = ±½ ×number of unpaired electrons Spin angular momentum =
s ( s + 1)
h 2p
Aufbau principle : The electrons are filled up in increasing order of the energy in subshells. 1s22s 22p 63s23p64s23d104p65s24d105p66s24f145d106p67s25f146d10 (n + l) rule : The subshell with lowest (n + l) value is filled up first, but when two or more subshells have same (n + l) value then the subshell with lowest value of n is filled up first. Pauli exclusion principle : Pauli stated that no two electrons in an atom can have same values of all four quantum numbers. Hund's rule of maximum multiplicity : Electrons are distributed among the orbitals of subshell in such a way as to give maximum number of unpaired electrons with parallel spin.
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IMPORTANT NOTES
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Chemistry HandBook
CHAP TER
ALLEN
CHEMICAL KINETICS —
x = order of reaction w.r.t. A y = order of reaction w.r.t. B x+y = n (overall order of reactions) Order is an experimental quantity It may be 'o', +ve, -ve or fractional Unit of K = [mol L-1]1-n× time—1 = (atm)1-n × time—1 K depends upon temperature, catalyst & nature of reactant.
COMPLEX R EACTIONS These type of reactions complete in multi step : Eg. : 2N2O5 ®4NO2 + O2 (Fast)
(ii) NO 2 + NO3 ® NO 2 + NO + O2 (Slow) (iii) NO + NO3 ® 2NO 2
—
OI +Cl
! Mo l e cu l a ri t y i s t h e
!
!
total number of reacting species participating in an elementary reaction. It is a theoret ical quantity & have only "integer values (i.e. 1,2,3). Molecularity >3 is very rare.
Pseudo First Order Reaction
These type of reactions complete in single step. If n1A+n2B ®Product n1 n2 Rate law = k[A] [B] Order = n1 + n2 For elementary reaction fractional order is not possible. In elementary reaction molecularity is equal to its order. Zero order reactions can never be an elementary reaction.
where, K = Rate constant or specific reaction rate.
(i) 2N2O5 2NO2 + 2NO3
—
ELEMENTARY R EACTIONS
Rate Law (Experimental Expression) x y Rate = K[A] [B]
l
OH—
the experimental observations are given below Exp. [OCl—] [I—] [OH—] d[IO —]/dt 1 0.0017 0.0017 1.0 1.75 2. 0.0034 0.0017 1.0 3.50 3. 0.0017 0.0034 1.0 3.50 4. 0.0017 0.0017 0.5 3.50 From experimental observations : Rate law = k[OCl—][I—]/[OH—] Order =1
*Rate of Disappearance of A=-d[A]/dt *Rate of Disappearance of B=-d[B]/dt *Rate of Appearance of C = +d[C]/dt *Rate of Appearance of D = +d[D]/dt —1 —1 *Unit of ROR = mol L time *ROR is always positive.
l
—
For the reaction OCl +I
Instantaneous or Average Rate of Reaction
l
Molecularity
EXPERIMENTAL OBSERVATIONS
n1A + n2B ® n 3C + n4D
Reactions having order =1 and molecularity > 1 Eg. : wHydrolysis of Ester in acidic medium. w Inversion of cane sugar.
Reactant taken in excess can't affect order of reaction
ZERO ORDER R EACTIONS E.g. : 1. Decomposition of Gases on metal surface. 2. Photochemical Reactions. 3. Enzyme catalysed reactions. Differential Rate Equation :
(Fast)
r=-d[A]/dt = k[A]0
Here rate law is written in terms of slowest step
Integrated Rate Equation
(R.D.S.) which must be free from intermediates.
[A]t = [A]0 — kt
; x=kt
Rate law = K[N2O5], Order =1 Molecularity of each reaction step is defined separately. Total molecularity of complex reaction is not defined. If not defined is not in the option then molecularity of the slowest step is equal to order of reaction. (Then in this case molecularity will be 1)
24
t1/2 = t50%=
[A]0 [A]0 ; t100% = =2t1/2 2k k
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R ATE OF REACTION
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Chemistry HandBook
CHAP TER
ALLEN
FIRST O RDER REACTION
th
n ORDER R EACTION
Eg. 1. All Radioactive decay 2. Pseudo First order reaction.
kt=
Integrated Rate Equation [A]0 kt = 2.303 log [A]t
Differential Rate Equation 1 r=-d[A]/dt = k[A]
n-1
1 2 1 ; n¹1 kt1/2= (n-1) [A]0n-1 1 n-1 [A]0 l It is half life method to determine order of reaction. l Hydrolysis of ester in alkali medium is second order reaction. t1/2µ
t½=t50%=0.693 k t¾=t75%=2t½
TEMPERATURE
COLLISION T HEORY
f Reacting molecules must possess a minimum amount of energy known as Threshold Energy (TE) f (ii) Proper orientation of collision. (i)
Radiation
Progress of reaction Endothermic (DH = +ve)
Concentration
DH
(E a )b (T.E.)
Activated complex
(E a)f P.E.
DH
(T.E.)
(E a)f
(Ea) b
P.E.
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Energy
Activated complex
kT+10 = 2 to 3 kT r2 k2 DT/10 r1 = k1 =m
m=
Nature of Reactant
TE = Potential energy of reactant + Activation Energy (Ea) Energy
1 1 1 ; n¹1 (n-1) [A]tn-1 [A]0n-1
Pressure
(b) k=Ae
—Ea/RT
n
(Arrhenius Eq )
A = Arrhenius constant / Frequency factor / pre-exponential factor Ea = Activation Energy R = Gas Constant T = Temperature (K) e—Ea/RT = Boltzmann factor —Ea/RT k/A = e = Fraction of molecules having energy ³ Ea
Progress of reaction Exothermic (DH = -ve)
DH = (Ea)f-(Ea)b = HP - HR Factors Affecting Activation Energy (a) Nature of Reactant (b) Catalyst Positive CatalystÞ ¯T.E. Þ ¯Ea ÞRate Negative CatalystÞ T.E.Þ Ea Þ¯Rate
Catalyst
log10 k= log10A—
Ea 2.303RT
Temperature
25
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THERMODYNAMICS DEFINITION
INTERNAL ENERGY (U) or (E)
Deals with interaction of one body with
Sum of all molecular level energies. It is state function, depends on temperature and extensive property.
another in terms of energy. System : Part of universe under investigation
For Ideal gas : DU = nCV DT
Surrounding : Rest part of universe except system. For chemical reaction :
Boundary : Devide system & surrounding
DrE = SEprod – SEreact ¹ 0 at given T.
SYSTEM Open
Closed
isolated
Energy and matter
Only energy
Neither energy
can exchange
can exchange
nor matter
HEAT (q) Energy exchange due to temperature difference :
State function
Path function
Properties which depends only
Depends on
on initial & final state of system
path or process.
& not on process or path.
as well as intial
s = specific heat capacity
and final state
m = Amount of substance
q = msDT
C = heat capacity Cm = molar heat capacity
of the system. e.g. U, H etc.
q = nCmDT,
q = CDT,
e.g. work, heat WORK (W)
THERMODYNAMIC PROPERTIES Intensive Properties which are independent of matter (size & mass) present in system. e.g. Pressure, temperature, Melting point, density etc.
Isothermal Isochoric Isobaric Adiabatic V = const. P = const.
V2
ò
Wrev = - Pext × dV
Wirr = – Pext(V2–V1)
V1
SIGN CONVENTION
PROCESSES T = const.
Irreversible
No heat
Cyclic Initial &
exchange final state q =0
w
(+)ve
q
of system are same
Reversible process
Irreversible process
•
Slow process
• Fast process
•
At any time system
• No equilibrium between
and surrounding are
system and surrounding
in equilibrium. •
28
Psys = Psurr ±dP
• Psys = Psurr ±DP
system w
(- )ve
q
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Extensive Properties which are dependent of matter (size & mass) present in system e.g. Mass, volume, heat capacity etc.
Reversible
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FIRST LAW OF THERMODYNAMICS (FLOT)
SECOND LAW OF THERMODYNAMICS (SLOT)
Law of conservation of energy
In an irreversible process (spontaneous process) entropy of universe increases. DSsystem + DSsurr = DSuniv DSuniverse
DU = q + W
WORK DONE IN VARIOUS PROCESS Isochoric
Isobaric
Free expansion
W =0
W= –Pex(V2–V1)
Pext =0
DU=qV=nCVDT qP=nCVDT
Zero Reversible
(+) ve (-)ve spontaneous Non-spontaneous
ENTROPY(S) State function, extensive property measurement of randomness a disorderness. Sgas > Sliq > Ssolid
W=0, DU=0,q=0
Isothermal dT =0; DU=0 (for Inert gas); q =–W
S as temperature ; DS = Reversible Isothermal
Irreversible Isothermal
æV ö Wrev =-nRTln ç 2 ÷ è V1 ø
é nRT nRT ù Wirr = -Pext ê P1 úû ë P2
æT ö æV ö DS = nC V ln ç 2 ÷ + nRln ç 2 ÷ è T1 ø è V1 ø æT ö æP ö DS = nCP ln ç 2 ÷ + nRln ç 1 ÷ è T1 ø è P2 ø Reversible phase transformation :
æP ö = - nRTln ç 1 ÷ è P2 ø
DS fusion =
Adiabatic : Þ
q=0
C g= P CV
DU =W= nCVDT Þ W =
CP = molar heat capacity at constant P.
CP–CV=R Þ
CV = molar heat capacity at constant V.
Dr S =
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PVg = constant (Ideal gas)
E
TVg–1 = constant (Ideal gas)
Dr G =
Enthalpy (H) pressure, depend on temperature.
For reaction : DH = DU + DngRT
åD G f
0
( prod ) - å D f Go ( react)
DG=DGo + RTlnQ (Rev. Rxn) At equilibrium DG =0, Q = K DGo = –RTlnK
State function, extensive property, constant
DH = nCPDT = qP (Ideal gas)
å S ( product) - å S(Reactant)
Gibbs free energy (G) & spontaneity G : State function; extensive property G= H –TS DG = DH – TDS (at constant T & P) DG < 0 : Spontaneous process DG = 0 : At equilibrium DG > 0 : Non-spontaneous DG: Measurement of Non-pV work (useful work)
For Reversible adiabatic :
H = U + PV
DHvap DH fusion DS vap = ; TMP TBP
For chemical reaction :
P2 V2 - P1V1 g -1
Þ
q rev T
D rH — — — + + +
DrS + — — + + —
DrG — — + + — +
Description Reaction spontaneous at all temperatures (at low T) Reaction spontaneous at low temp. (at high T) Reaction non-spontaneous at high temp. (at low T) Reaction non-spontaneous at low temp. (at high T) Reaction spontaneous at high temp. (at all T) Reaction non-spontaneous at all temp.
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ALLEN
THERMOCHEMISTRY (ENERGETICS)
ENTHALPY OF FORMATION (D fH) (May be endothermic or exothermic) Change in enthalpy when one mole of a substance is formed from its constituent elements present in standard state. * For elements DfHo = 0 (for standard state) DfHo [O2(g)] =0, DfHo = S8(rhombic) = 0 o DfH [P4 (white)]=0, DfH0 = C(graphite) = 0 D r Ho =
åD H f
o
( prod.) - å D f Ho ( react.)
ENTHALPY OF COMBUSTION (DCH) (always exothermic) Change in enthalpy when 1 mole of a substance is completely burnt in oxygen. 7 C2H6 ( g) + O2 ( g ) ® 2CO2 ( g ) + 3H2O( l ) ; D CHëéC2 H6 ( g)ûù 2
å
D r Ho =
D C Ho ( react.) -
Calorific value =
å
D C Ho ( prod.)
DHcomb molecular wt
ENTHALPY OF TRANSITION Enthalpy change when one mole of one allotropic form changes to another. C( graphite ) ® C( diamond) D tran Ho = 1.9 kJ mol -1
H2O(l) ®H2O(g); DvapHo (H2O(l)) H2O(S) ®H2O(l); DfusHo (H2O(s)) H2O(S) ®H2O(g); DsubHo (H2O(s)) LAWS OF THERMOCHEMISTRY A ® B D r H = x kJ mol -1 ïü ý Lavoisier & Laplace law (i) B ® A D r H = - x kJ mol -1 ïþ
(ii) Hess Law of Constant Heat summation C
DH1 A DH3
30
DH2
DH D
B E
DH4
DH5
DH=D H1 +D H2 or DH=D H3+D H4+D H5 or DH=D H1+D H2=D H3+D H4+D H5
BOND ENTHALPY (Always endothermic) Average amount of enthalpy required to dissociate one mole gaseous bond into separate gaseous atoms. æ Sum of bond enthalpy ö æ Sum of bond enthalpy ö Dr H = ç ÷-ç ÷ è of gaseous reactant ø è of gaseous product ø
RESONANCE ENERGY DHoresonance = D f H o (experimental) - D f Ho (calculated) = D C Ho (calculated) - D C Ho (experimental)
ENTHALPY OF NEUTRALIZATION (DHneut) (Always exothermic) Change in enthalpy when one gram equivalent of an acid is completely neutralized by one g-equivalent of a base in dilute solution. SA + SB ® salt + water ; DHoneut H+(aq) + OH–(aq) ® H2O(l) ; DH =– 13.7 kCal eq–1 = 57.3 kJ eq–1 o In case of weak acid / base or both DHN < 13.7
Kcal eq
and the difference is enthalpy of ionisation of ionisation of weak species except in case of HF when DHN > 13.7 due to hydration of F–. ENTHALPY OF ATOMISATION (DHatom) (always endothermic) Change in enthalpy when one mole of molecules converts into gaseous atoms. ENTHALPY OF SOLUTION (DHsol) (may be endo or exothermic) Change in enthalpy when 1 mol of a substance is dissolved in excess of water so that further dilution does not involve any heat change. aq
CuSO4( s) ¾¾® CuSO4( aq) ; DHo( sol.) ENTHALPY OF HYDRATION (DHhydra) (always exothermic) Enthalpy change when 1 mole of anhydrous salt combine with requisite amount of water to form hydrated salt. o CuSO4( s) + 5H2 O( l) ® CuSO 4 .5H2 O( s) ; DH hyd (anhy. salt)
(hydra.salt)
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ENTHALPY OF REACTION (DHR) Amount of heat evolved or absorbed during a reaction at constant pressure.
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ENTHALPY OF HYDROGENATION (DHhydro) (Always exothermic) Enthalpy change during the complete hydrogenation of one mole unsaturated organic compound into its saturated compound. unsaturated organic compound
( = or º bond )
D
¾¾®
saturated organic compound
( - bond)
C2H2 + 2H2 ®C2H6; DHhydro
NOTE : If in a reaction heat of reactant & products are given then heat of that reaction can be measured as follows: (a) For heat of combustion & for bond enthalpy
å ( DH ) D H = å ( B.E.)
Dr H =
C reactant
r
reactant
å ( DH ) - å ( B.E.)
-
C product product
(b) For heat of formation Dr H =
å ( DH )
f product
-
å ( DH )
f reactant
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IMPORTANT NOTES
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ALLEN
CHEMICAL EQUILIBRIUM 5
Equilibrium represents the state of a process in which the measurable properties like :- temperature, pressure, color, concentration of the system do not show any change with the passage of time.
5
Equilibrium is a dynamic process, chemical equilibrium can be approached from both sides of reaction.
5
The state of equilibrium is not affected by the presence of catalyst. It only helps to attain the equilibrium state in less or more time.
5
Equilibrium can be attained both in homogeneous & heterogenous system.
GRAPHS
Consider a reversible reaction, rf aA + bB cC + dD
Rate of forward reaction (rf) = rate of backward reaction (rb) So, at equilibrium,
Reactants
[ XC ]c [ XD ]d [ XA ]a [ XB ]b
In terms of mole fraction
rb
The active mass of solid & pure liquid is a constant quantity (unity) because it is an intensive property.
B
32
then KP = KC
when Dng > 0
then KP > KC
when Dng Keq then system proceed in backward direction
2
when n=2, then K¢¢C = K n=
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(c)
E
(d)
1 3
to attain equilibrium. If Q < Keq then system proceed in forward direction 1/ 3
to attain equilibrium.
then K¢¢C = K
5
A B
KC =K1
B C
KC = K2
CD
KC = K3 then
A D
KC = K1 × K2 × K3
AB
KC = K1
2C 2B
KC = K2
DC
KC = K3 then
AD
KC =
K1 K2 * K3
Degree of dissociation (a)
a=
5
No. of moles of reactant dissociated No. of mole of reactant present initially
Degree of Dissociation from Vapour density n1A(g) n2B(g) + n3C(g) a=
n1 æ D T - D0 ö ç ÷ Dn g è D0 ø ; Dng =(n2 + n3)–(n1)
DT = theoretical vapour density =
Molecular weight of A 2
D0 = Observed vapour density
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PHYSICAL EQUILIBRIUM Physical reaction : Those reactions in which change in only & only physical states of substances takes place without any chemical change. (i)
Ice-water system (melting of ice) : Ice
(s) (more volume)
(ii) Water -Water vapour system (vapourisation of water) :
+ Heat water( l )
water
(l) (less volume)
(less volume)
It is an endothermic process & there is decrease in volume. Thus, the favourable conditions for melting of ice are high temperature, & high-pressure.
vapour( g)
(more volume)
It is an endothermic process & there is increase in volume. thus, the favourable conditions for vaporisation of water are high temperature, & lowpressure.
(iii) Solubility of gases in liquids : Gas(g) + water(l) Aqueous solution(l) It is an exothermic process, there is decrease in volume. thus, low temperature and high pressure will favour the dissolution of a gas in liquid. LE-CHATELIER’S PRINCIPLE If a system at equilibrium is subjected to a change of any one of the factors such as concentration, pressure or temperature then the equilibrium is shifted in such a way as to nullify the effect of change. Le-Chatelier’s principle is applicable for both chemical and physical equilibrium.
CHEMICAL EQUILIBRIUM
No. a)
b)
c)
d)
e)
34
Effect due to change in Concentration
Pressure
Temperature
Dissociation
Dng =0
Dng > 0
Dng < 0
AB
A2B
2AB
(i) [A]
Forward direction
Forward direction
(ii) ¯ [A]
Backward direction
Backward direction
(i) in pressure
Unchanged
Backward direction
(ii) ¯ in pressure
Unchanged
Forward direction
(i) in Endothermic Forward direction
Forward direction
(ii) in Exothermic Backward direction
Backward direction
Forward direction Backward direction Forward direction Backward direction Forward direction Backward direction
(i) in pressure
Unchanged
Dissociation Decreases
Dissociation Increases
(ii) in volume
Unchanged
Dissociation Increases
Dissociation Decreases Dissociation Decreases
Mixing of
(i) at constant P
Unchanged
Dissociation Increases
inert gas
(ii) at constant V
Unchanged
Unchanged
Unchanged
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IONIC EQUILIBRIUM ACID
BASE
Strong
Strong
Weak HClO3 HClO2 HClO H3PO4 H3PO2 H3PO3 H2S
H2CO3 HNO2 H2SO3 HCN H3BO3 HF Almost all organic acid Like : acetic acid oxalic acid
HClO4 HI HBr H2SO4 HCl HNO3
Weak
Group-1 hydroxide (except-LiOH) NaOH KOH RbOH Group-2 hydroxide except Be(OH)2 and Mg(OH)2 **Ca(OH)2 Sr(OH)2 Ba(OH)2
All other bases like NH4OH Zn(OH)2 Al(OH)3 Fe(OH)3 Cu(OH)2 etc.
ACID BASE THEORIES ARRHENIUS CONCEPT Acid :
Base :
Which produce H ion in aqueous solution.
which produce OH– ion in aqueous solution.
e.g. HCl, H2SO4, HClO4, H3PO4, CH3COOH
e.g. NaOH, Mg(OH)2, Ba(OH)2
+
Major Limitation :
but H3BO3 is not a Arrhenius acid.
Defined only in water solvent.
BRONSTED-LOWRY CONCEPT
Base : which accepts H+ in any solvent.
•
To find conjugate base of any Acid ® Remove one H+
•
To find conjugate acid of any Base ® add one H+
HCl + NH3 Cl A cid
B ase
—
C o nju g ate B ase
+ NH4
+
C o nju g ate A cid
•
Water is Amphiprotic solvent (can accept as well as lose H+)
H2O H++OH– H2O + H+ H3O+ Major Limitation : Does not explain acidic behaviour of aprotic acids e.g. SO2, SO3, CO2, AlCl3, SiCl4
36
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Acid : Which gives H+ in any solvent.
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LEWIS THEORY BASE
ACID TYPES OF LEWIS BASE 1. Neutral molecule having lone pair
1.
Having Incomplete octet :
g g
2.
Having vacant d-orbitals: Having multiple bonds between atoms of different EN:
2.
CO, SO2, SO3 etc. 4.
Cations : Ag+, Li+, Al+3, Mg2+ false cations
gg
gg
gg
gg
H - O- H , R - O- R etc.
SF4, SF6,SnCl2, SnCl4 etc. 3.
(which cannot act as
Lewis acid) :
NH4+, H3O+, PH4+ etc.
Anions : O–2, SO42–, CO32–, Cl–, Br–, I–, CH3COO– etc. • All the Lewis bases are Bronsted bases but all the Lewis acids are not Bronsted acids. • All Arrhenius acids are Bronsted acid but it is not so for bases.
FOR PURE WATER
OSTWALD’S DILUTION LAW (Only for weak electrolytes)
1. [H+] = [OH–]
a µ dilution dilution Þ a
OSTWALD’S DILUTION LAW
EXPLANATION OF WATER H2O H+ + OH– Kw = Ionic product of water
2. pH = pOH
K
•
is always less than pH
= dissociation constant of water Kw = H O éëQ [ H2O] = 55.5ùû [ 2 ]
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KW = [H+][OH—]
E
PKw 2 pH of an acidic solution
3. (PH)pure water =
pKw= pH + pOH K
g g
g g
N H3 , R - N H2 , R2 - NH ,
BF3, BCl3, B(OH)3, AlCl3 etc.
Lewis base is an electron pair donor
Lewis acid is an electron pair acceptor.
TYPES OF LEWIS ACID
of pure water. •
pH of an basic solution is always greater than pH of pure water.
DIFFERENT VALUES AT DIFFERENT TEMPERATURE At 25°C 1. Kw=10-14 2. (pH)pure water =(pOH)pure water =7 3. pH + pOH = 14
on increasing temperature Kw on increasing temperature (pH)pure water decreases
At 90°C 1. Kw=10-12 2. (pH)pure water =(pOH)pure water =6 3. pH + pOH = 12
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pH OF DIFFERENT SOLUTIONS Type I : Single Substance CASE-1 Strong Acid : [H+] = NAcid+10–7
CASE-2 Strong Base: [OH–]=NBase+10–7(from
(from water)
water)
pH = – log [H+] We neglect smaller values (in Nacid + 10–7) if it is atleast 100 times smaller than other.
We can neglect smaller values. If it is atleast 100 times smaller than other. pOH = –log [OH–] pH = pKw –pOH
CASE-3 Weak acid : (for monobasic acid)
[ H+ ] =
CASE-4 Weak base: (for monoacidic base)
[OH- ] =
Ka C
Ka = dissociation constant of acid C : Initial concentation of acid
KbC
Kb = dissociation constant of base C : Initial concentration of base
Type II : More than one substances (Non-reacting CASE-5 : (SA)I + (SA)II
Initially same Beaker (If individual volumes are not given) +
[H ] = N1 + N2
CASE-6 : (SB)I + (SB)II
Same Beaker (Initially)
Initially in different beaker (Individual volumes are given) N1V1 + N2V2 + [H ] = V1 + V2
CASE-7 : SA + WA or SB + WB We can ignore [H+] / OH—
Different Beaker (Initially)
—
[OH ]=N1+N2 [OH—]=
coming from weak part as compared to strong part due to
N1V1 + N2V2 V1 + V2
common ion effect.
Type III : More than one substances (Reacting) + SB ® Salt of SASB + H2O Case 8 : NSA N2 V2 1V1
If N1V1 = N2V2
b)
Then salt of SASB is left in beaker after reaction.
If N1V1 > N2V2
c)
Then SA + salt of SASB is left in solution among which only SA is the contributing substance towards pH.
Salt of SASB : • Does not hydrolyse • Solution remain neutral (pH = 7 at 25°C)
[ H+ ] =
If N1V1 < N2V2 Then SB + salt of SASB is left in solution among which only SB is contributing substance towards pH.
N1V1 - N2 V2 V1 + V2
[OH- ] =
N2 V2 - N1V1 V1 + V2
+ SB ® Salt of WASB + H2O Case 9 : WA N1V1 N2 V2
a)
If N1V1 = N2V2 [ left :- salt of WASB]
b) If N1V1 > N2V2
Salt of WASB : Anionic hydrolysis
[left : WA+ salt of WASB] Acidic buffer
Þ Kh =
Kw ; h= Ka
Þ pH = 7 +
38
Kh C
1 [pK a + log C] 2
pH = pKa + log
( pH > 7 )
[ salt ] [ acid]
([C]in normality)
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+ WB ® Salt of SAWB + H2O Case 10 : NSA N2 V2 1V1
a)
If N1V1 = N2V2 [left : salt of SAWB] Salt of SAWB : Cationic hydrolysis Kh =
Kw h= Kb ;
pH = 7 -
b)
+ WB ® Salt of WAWB + H2O Case 11 : WA N1V1 N2 V2
If N1V1 = N2V2 [left : salt of WAWB] Salt of WAWB : Cationic anionic or anionic cationic hydrolysis
Kh C
Kh =
1 [ pK b + log C ]; 2
[ pH < 7]
pH = 7 +
If N1V1 < N2V2
1 [pKa - pKb ] 2
pH & h is independent of ‘C’.
[left : WB + salt of SAWB] basic buffer æ [ salt ] ö pOH = pKb + log çè [ base ] ÷ø
Kw ; h = Kh Ka × Kb
[pH can > 7, < 7 or = 7 depends on value of Ka & Kb]
SOLUBILITY(s) & Solubility Product (Ksp) Solubility :
Ionic Product [Qsp]
The maximum amount of solute that can be dissolved in a particular amount of solvent at a given temperature is called solubility(s). It is generally expressed in molarity.
AxBy xA+y + yBx– ; Qip = [ A y + ] [ B x - ]
AgCl ( s )
AgCl ( aq) ®
Ag+ + Cl -
dissociation
dissolution
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In Qip the concentration taken are at any time but in Ksp the concentration are at equilibrium time / saturation time. Applications : 2. If Qip = Ksp [ saturated]
–
3. If Qip > Ksp [super saturated / ppt. will form]
Ksp = [Ag ] [Cl ]
Effect of common ion
depends only on temperature.
•
+
y
1. If Qip < Ksp [ unsaturated]
Solubility Product (Ksp): +
x
–
Expressions of Ksp : AxBy xA+y + yBx– x
y
General form Ksp = [ Ay + ] [ Bx- ]
In terms of ‘S’ : Ksp = ( xS ) x ( yS ) y
Presence of common ion decreases the solubility but has no effect on Ksp as it depends only on temperature.
Effet of odd ion •
Presence of odd ion increases the solubility but has no effect on Ksp.
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CH APTER
Group
Radicals
ALLEN
Condition for
Forms of
precipitation
precipitation
(Group reagent) Zero
Na+,K+, NH +4
First
Pb , Hg ,
By mixing of
Chloride
( Hg ) , Ag+
dilute HCl
AgCl, Hg2Cl2, PbCl2
Pb+2, Cu+2, Hg+2, Cd+2, Bi+3, As+3, Sb+3, Sn+2,Sn+4
H2S gas passed in the presence of acidic medium
Sulphide PbS,HgS, CuS,CdS, SnS, SnS2 ,As2S3, Sb2S3 , Bi2S3
Third
Al+3, Cr+3, Fe+3
NH4OH mixed in the presence of NH4Cl
Hydroxide Al(OH)3, Fe(OH)3 Cr(OH)3
Fourth
Zn+2, Ni+2, Mn+2,Co+2
H2S gas passed in presence of
Sulphide MnS, CoS,
basic medium
NiS, ZnS
1-2 drops of
–
CH3 COOH +1
+2 2
Second
Fifth
Ba+2, Sr+2, Ca+2
(NH4)2 CO3 mixed in the presence of NH4Cl
Carbonate BaCO3, SrCO3, CaCO3
Sixth
Mg+2
By mixing of Na2HPO4
Hydrogen phosphate (MgHPO4)
Name of indicator
Colour
Colour
Working
in acidic
in basic
pH range
medium
medium
of indicators
KEY POINTS
Methyl orange (MeOH)
Pinkish red
Yellow
3.1 to 4.5
Methyl red
Red
Yellow
4.2 to 6.2
O
Phenol red
Yellow
Red
6.2 to 8.2
Buffer capacity
Phenolphthalein (HPh)
Colourless
Pink
8.2 to 10.2
=
No. of moles of H+ /OH - added per litre change in pH of buffer solution
O
ACID-BASE TITRATION Type of
pH range of
Suitable
titration
titration
indicators
Maximum buffer action when [salt] = [acid]
3 – 11
All indicators
O
SA/SB.
(MeOH, HPh etc.) SA/WB
3–7
Methyl orange (MeOH) and methyl red
WA/SB
7 – 11
Phenolphthalein (HPh)
WA/WB
40
6.5 – 7.5
Phenol red
pH of Amphiprotic species :(NaH2PO4, NaHCO3) which can donate as well as accept H+ pH=
pK a1 + pKa2 2
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CH APTER
ALLEN
SOLID STATE DEFECTS STOICHIOMETRIC DEFFECT Schottky Equal no. of cation & anion are missing from their respective sites.
IMPURITY DEFECT
Frenkel Smaller ion leaves its appropriate site & occupies an interstitial site.
NON-STOICHIOMETRIC DEFFECT
CORNERS FACES EDGES BODY CENTRE BODY DIAGONAL FACE DIAGONAL FACE CENTRES EDGE CENTRES
Metal Deficiency Defect Eg. Fe0.93O to Fe0.96O Metal excess defect due to the presence of extra cation at interstitial site.
8 6 12 1 4 12 6 12
Metal excess defect due to anionic vacancies (anion is absent from its site which is occupied by an electron). This site is called F-centre. Limiting Radius Ratio
Coordination No. of cation
Geometry of Void
0.155 £ r/R < 0.225
3
Plane Trigonal
0.225 £ r/R < 0.414
4
Tetrahedral
FCC, HCP
0.414 £ r/R < 0.732
6
Octahedral
FCC, HCP
0.732 £ r/R < 1.000
8
Cubical
SC
Void found in
Location of void
No. of void per atom
Example Boron oxide (B2O3)
2
ZnS, SiO2, Na2O, CaF2
Body centre & edge centres
1
NaCl, MgO
Body centre
1
CsCl
Classification of solid on the basis of nature of order of arrangement of constitutent particles These solids have definite characteristic shape Definite melting point & heat of fusion Cleavage surfaces are smooth Anisotropic in nature. Long range order. Ex. : NaCl, Quartz, Metal, Diamond etc.
42
AMORPHOUS These solids have irregular shape. Indefinite melting point & heat of fusion. Cleavage surface are irregular. Isotropic in nature. Short range order. Ex. Glass, Quartz Glass, Rubber, Plastics etc.
Name of system
Axis
Angles
1. Cubic 2. Tetragonal 3. Orthorhombic or Rhombic 4. Monoclinic 5. Triclinic 6. Rhombohedral or Trigonal 7. Hexagonal
a=b=c a=b¹c a¹b ¹c a¹b ¹c a¹b ¹c a=b=c a=b¹c
a=b=g=90° a=b=g=90° a=b=g=90° a=g=90°, b ¹ 90° a ¹ b ¹ g ¹ 90° a=b=g ¹ 90° a=b=90°, g=120°
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CRYSTALLINE
E
S. No.
Type of Ionic Crystal NaCl (1:1) (Rock salt Type)
1.
Chemistry HandBook
CHAPTER
ALLEN
Geometry
Coordination Number
No. of formula per U.C.
6:6
4Na + 4Cl 4NaCl (4)
—
Cl : Every lattice point of CCP CCP + Na : At Every OHV
+
—
Examples l l l
CsCl Type (1 : 1)
2.
3.
ZnS Type (1:1) (Zinc Blende Type) (Sphalerite)
4.
CaF2 Type (1:2) (Fluorite Type)
Na2O Type (2:1) (Antifluorite Type)
5.
ZnS Type (1:1) (Wurtzite) another geometry of ZnS
6.
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S. No.
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Contents
1.
Geometry
2.
Arrangement
3.
-2
S : Every lattice point of CCP CCP +2 Zn : At 50% of THV or At Alternate THV Ca+2 : Every lattice point of CCP CCP — F : At every THV
1Cs+ + 1Cl— 1CsCl (1)
8:8
Cl— : At Every Corner BCC Type + Cs : At Body centre
+
—2
O : Every lattice point of CCP
—2
4O
: 8
4
—2
S : Every lattice point of HCP HCP +2 Zn : 50% of THV or at alternate THV SC
+2
—1
BaCl2, BaF2, SrCl2, SrF2, CaCl2, CaF2
+
—2
Li 2O, Li2S, Na2O, Na2S, K2O, K2S
+2
—2
Same as Sphalerite
4Ca + 8F 4CaF2 (4)
8Na
CCP
BeS, BeO, CaO, AgI CuCl, CuBr, CuI
4Ca+2 8F—
+
Na : At every THV
4:4
BCC
Halides of 'Cs' TlCl, TlBr, CaS
—2
4Zn + 4S 4ZnS (4)
: 4
l
+2
4:4
8
l
Halides of (Li, Na, K, Rb); Oxides & sulphides of Alkaline earth metals; (some exception) AgF, AgCl, AgBr, NH4X
8Na + 4O 4Na2O (4) 6Zn + 6S 6ZnS (6)
FCC/CCP
HCP
AAAA... Packing close packing
ABAB... Packing but not close packing
No. of atoms per UC
1
2
4
6
4.
Coordination No.
6
8
12
12
5.
a & r relation
r = a/2
r =aÖ3/4
r =a/2Ö2
6.
Packing Efficiency
p/6 or 52.4%
pÖ3/8 or 68%
p/3Ö2 or 74%
7.
Example
Mn
IA ; Group:V&Cr; Ba, Fe
ABCABC... Close Packing
ABAB... Close Packing
p/3Ö2 or 74% Remaining d-block elements, Be & Mg
43
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Chemistry HandBook
44 ALLEN
IMPORTANT NOTES
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ALLEN
E Chemistry HandBook
IMPORTANT NOTES
45
Chemistry HandBook
CH APTER
ALLEN
SURFACE CHEMISTRY Classification based on interaction of phases :-
LYOPHILIC AND LYOPHOBIC SOLS
Colloidal solutions in which the dispersed phase has considerable affinity for the dispersion medium, are called lyophilic sols (liquid – loving). For example - dispersion of gelatin, starch, gum and proteins in water. Colloidal solutions in which the dispersed phase has no affinity or attraction for the dispersion medium are called Lyophobic colloidal (liquid hating) solutions. COMPARISION OF LYOPHOBIC AND LYOPHILIC SOLS Lyophilic sol (Emulsoid)
Lyophobic sol (suspensoid)
1. Preparation
Can be easily prepared by shaking or warming the substance with liquid
Can not be prepared easily, special methods are required
2. Stability
are more stable
are less stable
3. Reversibility
are reversible
are irreversible
4. viscocity
viscocity is much higher than that of
viscocity is nearly same as that of the
dispersion medium
dispersion medium
5. Surface tension Surface tension is usually low 6. Hydration or solvation 7. Charge
Surface tension is almost same as that of dispersion medium
These are highly solvated as the particles
These are less solvated as the particles have less
have great affinity for solvent
affinity for the dispersion medium
The particles have little charge or no
The particles carry a characteristic charge
charge at all
either positive or negative
8. Visibility
Particles can not be seen under microscope
Particles can be seen under microscope
9. Tyndall effect
Less Scattering
More Scattering
10. Migration in electric field 11. General Ex.
PE
ON TI A IZ PT
may or may not migrate as they may
migrate towards anode or cathode as these
or may not carry charge.
particles carrry charge.
Mostly of organic nature
Mostly of Inorganic nature
Ex. Gelatin, Starch,
Ex. Transiton metal salt in water like
Gum, Albumin & Cellulose Solution
Gold, As etc.
The dispersion of a freshly precipitated material into colloidal solution by the action of an electrolyte in solution is termed as peptization. The electrolyte used is called a Peptizing agent. Hardy Schulze Rule - This rule states that the precipitating effect of an ion on dispersed phase of opposite charge increases with the valency of the ion. The higher the valency of the flocculating ion, the greater is its precipitating power. Thus for the precipitation of As2S3 sol (–ve) the precipitating power of Al3+, Ba2+, and Na+ ions is in the order Al3+ > Ba2+ > Na+ Similarly for precipitating Fe(OH)3 sol (positive) the precipitating power of [Fe(CN)6]–3, SO42– and Cl– ions is in the order [Fe(CN)6]3–
>
SO42–
>
Cl–
The minimum concentration of an electrolyte in milli moles required to cause precipitation of 1 litre sol in 2 hours is called FLOCCULATION VALUE. The smaller the flocculating value, the higher will be the coagulating power of the ion.
Flocculation value a
46
1 Flocculation power
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Property
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Chemistry HandBook
CHAPTER
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The number of milligrams of a protective colloid (lyophillic colloid) that will just prevent the precipitation of 10 ml of standard gold sol on addition of 1 ml of 10% NaCl solution is known as Gold number of that protector (Lyophilic colloid).
GOLD NUMBER
The precipitation of the gold sol is indicated by a colour change from red to blue when the particle size just increases. The smaller the gold number of a protective Lyophilic colloid, greater is its protection power. Note : Gelatin and startch have the maximum & minimum protective powers respectively.
Protection Capacity a
1 Protection Number (Gold number)
TYPES OF COLLOIDS ACCORDING TO THEIR SIZE Multi Molecular
Macro Molecular
Associated colloids
Formation by aggregation of a large number of atoms or smaller molecules of substance.
Macromolecules in suitable liquid form colloid solution in which size of macro molecules may be in colloidal rang. These are polymers with high molecular mass.
Ex. ® Gold Sol (Au) Sulphur sol (S8)
Ex. ® Starch, Cellulose, Protein etc.
These are the substances which behave as normal electrolytes at low concentration but get associated at higher concentration and behave as colloidal solutions. These associated particles are also called micelles. Ex. ® Soap & Detergent
E
Physical Adsorption
Chemical Adsorption (Activated ad.)
1.
It is caused by intermolecular vander waal’s forces.
It is caused by chemical bond formation.
2.
It is not specific.
It is highly specific.
3.
It is reversible.
It is irreversible.
4.
Heat of adsorption is low. – 20 to –40 KJ/mol
Heat of adsorption is high. –80 to –240 KJ/mol
5.
No appreciable activation is energy is involved.
High activation energy involved.
6.
It forms multimolecular layers on adsorbent surface.
It forms unimolecular layer under high pressure.
C H G A E R N A E C R C AT O TER AL A F IS LY TI ST C S S
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COMPARISON OF PHYSI-SORPTION AND CHEMI-SORPTION
(i)
(ii) (iii) (iv) (v)
Critical temperature increases Ease of liquification increases Extent of adsorption increases (true for physisorption)
A catalyst remains unchanged in mass and chemical composition but can change their physical state. Only a very small amount of catalyst is sufficient to catalyse a reaction. A catalyst does not initiate a reaction. Solid catalyst is more efficient when used in finely divided form. Generally catalyst does not change the nature of products.
(vi)
(vii) (viii) (ix) (x)
A catalyst does not change the equilibrium state of a reversible reaction but helps to achieve the equilibrium state or position of equilibrium in lesser time. The catalyst are generally specific in nature. Changes rate constant of reaction. Does not change free energy of reaction and enthalpy of reaction. Participate in mechanism of reaction.
47
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Chemistry HandBook
48 ALLEN
IMPORTANT NOTES
E
INORGANIC CHEMISTRY
Chemistry HandBook
CHAP TER
ALLEN
Some Important Increasing Order 1. Acidic property (i) SiO2, CO2, N2O5, SO3 (ii) MgO, Al2O3, SiO2, P4O10 (iii) HClO, HClO2, HClO3, HClO4 (iv) CH4, NH3, H2O, HF (v) SiH4, PH3, H2S, HCl (vi) H2O, H2S, H2Se, H2Te (vii) HF, HCl, HBr, HI (viii) lnCl3, GaCl3, AlCl3 (ix) BF3, BCl3, BBr3, BI3 (ii) H2O, NH3, CH4, CO2 (iv) NO2—, NO2, NO2+ (vi) AsH3, PH3, NH3 (viii) NF3, NCl3 (x) OF2, OH2, Cl2O
2. Basic Character (i) LiOH, NaOH, KOH, RbOH, CsOH (ii) Be(OH)2,Mg(OH)2,Ca(OH)2,Ba(OH)2 (iii) BeO, MgO, CaO, SrO (iv) NiO, MgO, SrO, K2O, Cs2O (v) CO2, B2O3, BeO, Li2O (vi) SiO2, Al2O3, MgO, Na2O (vii) SbH3, AsH3, PH3, NH3 (viii) F—, OH—, NH2—, CH3—
ù (i) Li2CO3, Na2CO3, K2CO3, Rb2CO3, Cs2CO3 ú (ii) BeCO3, MgCO3, CaCO3, BaCO3 ú (iii) Be(OH)2, Mg(OH)2, Ca(OH)2, Sr(OH)2,Ba(OH)2ú Polarisation
ú ú úû
5. Solubility (i) BaCO3, CaCO3, MgCO3, BeCO3 (ii) Be(OH)2, Mg(OH)2, Ca(OH)2, Ba(OH)2 (iii) BaSO4, SrSO4, CaSO4, MgSO4, BeSO4 (iv) Li2CO3, Na2CO3, K2CO3, Rb2CO3, CsCO3 (v) LiOH, NaOH, KOH, RbOH, CsOH (vi) LiF, LiCl, LiBr, LiI (vii) LiF, NaF, KF, RbF, CsF (viii) BaF2, SrF2, MgF2, CaF2, BeF2 (ix) CaF2, CaCl2, CaBr2, Cal2 (x) AgI, AgBr, AgCl, AgF ù 1 ú Solubility µ covelent char. (xi) PbO2, Cdl2, RbI û
50
(i) Mg2+, Na+, F–, O2–, N3– (Hint : Isoelectronic series) (ii) Ca2+, Ar, Cl–, S2– (iv) B, Be, Li, Na
(iii) O, C, S, Se (v) F, O, F–, O2–
8. Oxidizing Power (ii) MnO42–, MnO4– (i) Cr2O72–, MnO4– (iii) WO3 , MoO3, CrO3 (iv) GeCl4, SnCl4, PbCl4 (v) I2, Br2, Cl2, F2 (vi) Zn+2, Fe+2, Pb2+, Cu2+, Ag+
4. Thermal Stability
(iv) LiOH, NaOH, KOH, RbOH, CsOH (v) BeSO4, MgSO4, CaSO4 (vi) CsH, RbH, KH, NaH, LiH (vii) SbH3, AsH3, PH3, NH3 (viii) H2Te, H2Se, H2S, H2O (ix) HI, HBr, HCl, HF
7. Atomic / Ionic Size
9. Ionization Energy (i) Na, Al, Mg, Si (ii) Li, B, Be, C, O, N, F, Ne, He (Ist I.P.) (iii) Be, C, B, N, F, O, Ne, Li, He (IInd I.P.) 10. Melting Point (i) Cs, Rb, K, Na, Li (ii) Mg, Ba, Sr, Ca, Be (iii) CaI2, CaBr2, CaCl2, CaF2 (iv) BeCl2, MgCl2, CaCl2, SrCl2, BaCl2 (v) NaI, NaBr, NaCl, NaF (vi) CsCl, RbCl, KCl, NaCl (vii) AlCl3, MgCl2, NaCl 11. Density (i) Na, Al, Fe, Pb, Au (ii) Li, K, Na, Rb, Cs (iii) Ca, Mg, Be, Sr, Ba (iv) Highest Density = Os/Ir (v) Lowest density = H (vi) Metal of lowest Density = Li
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2. Bond Angle (i) CH4, C2H4, C2H2 (iii) H2O, NH3, CH4, BH3 (v) H2Se, H2S, H2O (vii) PF3, PCl3, PBr3, PI3 (ix) NF3, NH3, NCl3
6. Ionic Character (i) LiBr, NaBr, KBr, RbBr, CsBr (ii) LiF, NaF, KF, RbF, CsF (iii) BeCl2, MgCl2, CaCl2, SrCl2, BaCl2 (iv) BCl3, AlCl3, GaCl3 (v) VCl4, VCl3, VCl2 (vi) AlF3, MgF2, NaF (vii) AlN, Al2O3, AlF3 (viii) HI, HBr, HCl, HF (ix) CuCN, AgCN (x) AgCl, KCl
E
12. Boiling Point (i) PH3, AsH3, NH3, SbH3 (iii) HCl, HBr, HI, HF (v) He, Ne, Ar, Kr (vii) H2, Cl2, Br2 13. Reactivity with water (i) Li, Na, K, Rb, Cs
(ii) H2S, H2Se, H2O (iv) NH3, HF, H2O (vi) H2O, D2O
(ii) Be, Mg, Ca, Sr, Ba
14. Extent of Hydrolysis (i) CCl4, MgCl2, AlCl3, SiCl4, PCl5 (ii) BiCl3, SbCl3, AsCl3, PCl3, NCl3 15. Bond Strength (i) HI, HBr, HCl, HF (ii) – C – I, – C – Br, – C – Cl, – C – F N – N, N = N, N º N As – H, Sb – H, P – H, N – H N22–, N2–, N2+, N2 O22–, O2–, O2 , O2+, O22+ LiI, LiBr, LiCl, LiF NaI, NaBr, NaCl, NaF CsCl, RbCl, KCl, NaCl BaO, SrO, CaO, MgO (vii) F2, H2, O2, N2 (viii) NO–, NO, NO+ (ix) I2, F2, Br2, Cl2 (x) O–O, S– S (xi) F – F, O – O, N – N, C – C, H – H (iii) (iv) (v) (vi)
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16. Reducing Power (i) PbCl2, SnCl2, GeCl2 (iii) Ag, Cu, Pb, Fe, Zn (v) H3PO4, H3PO3, H3PO2
E
Chemistry HandBook
CHAP TER
ALLEN
(ii) HF, HCl, HBr, HI (iv) HNO3, H2SO3, H2S
17. Covalent Character (i) LiCl, BeCl2, BCl3, CCl4 (ii) SrCl2, CaCl2, MgCl2 (iii) TiCl2, TiCl3, TiCl4 (iv) LiCl, LiBr, LiI (v) Na2O, Na2S (vi) AlF3, Al2O3, AlN (vii) HF, HCl, HBr, HI 18. Strength of Hydrogen bonding (X...H–X) (i) S, Cl, N, O , F (ii) NH3, H2O, HF 19. Ionic Radii in water (i) Cs+, Rb+, K+, Na+, Li+ (ii) Li+, Be+2 (iii) Na+, Mg+2, Al+3
21. Reactivity with Hydrogen (i) Cs, Rb, K, Na, Li (ii)Ba, Sr, Ca, Mg, Be 22. Reactivity Towards Air Be, Mg, Cs, Sr, Ba 23. Hydration of Ions/Hydration Energry (i) Ba+2, Sr+2, Ca+2, Mg+2, Be+2 (ii) Cs+, Rb+, K+, Na+, Li+ (iii) Na+, Mg+2, Al+3 24. Electron Affinity (i) I, Br, F, Cl (ii) Cu, Ag, Au (EA, of Au is very high = 222 kJ mol–1) (iii) O, S, F, Cl (iv) N, P, O, S 25. Electonegativity (i) As, P, S, Cl
(ii) I, Br, Cl, F
26. Bond Length (i) N2, O2, F2, Cl2 (iii) CO, C=O, –C–O–
(iii) C, N, O, F
(ii) NºN, CºN, CºC (iv) NO+, NO, NO—
(v) O2, O3, H2O2 (O-O bond length) (vii) N2, N2–, N2–2 (vi) CO, CO2, CO3–2 –2 – +2 (ix) HF, HCl, HBr, HI (viii) O2 , O2, O2, O2 27. Dipole moments (i) CCl4, CHCl3, CH2Cl2, CH3Cl (ii) NF3, NH3, HF, H2O (iii) Cis-chloropropene, Trans-chloropropene (iv) p, m, o-dichlorobenzene (v) CH3I, CH3Br, CH3F, CH3Cl (vi) NH3, SO2, HF, H2O (vii) H2S, H2O (viii) HI, HBr, HCl, HF (ix) PH3, ASH3, SbH3, NH3 (x) H2O, H2O2 28. Abundance of Elements (i) Elements on earth crust (ii) Metals on earth crust (iii) Non-metals In atmosphere In universe
- Fe, Al, Si, O - Ca, Fe, Al - Si, O - O, N - He, Si, H
20. Molar Conductivity in Water Li+, Na+, K+, Rb+, Cs+
51
52
Atomic radius Ionisation potential Electronegativity Electron affinity Covalent character of halides Metallic character Increases Oxidising nature Decreases Reducing nature Decreases Screening effect Decreases Effective nuclear charge (Zeff) Decreases Valency w.r.t. oxygen Increases Basic character of hydrides Decreases Basic character of oxides Increases Basic character of oxy acids Increases Strenth of oxy acids Constant Thermal stability of sulphate Constant Thermlal stability of carbonates (Metals)Increases Thermal stability of nitrates (Non metal) Decreases (Metals)Increases Thermal stability Increases of hydroxide Decreases Increases Density Increases Electro positivity Increases Increases Increases Increases
PERIODS
CHAP TER
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GROUPS
First increass then decreases Decreases
Decreases Increases Increases Increases Increases Decreases Increases Decreases Increases Increases Increases Decreases Decreases Decreases Increases Decreases Decreases Decreases Decreases
GENERAL TREND OF DIFFERENT PROPERTIES IN THE PERIOD AND GROPUS
Chemistry HandBook ALLEN
Some Important Increasing Order
E
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ALLEN
E CH APTER
Chemistry HandBook
PERIODIC TABLE
53
Chemistry HandBook
C HAP TE R
ALLEN
MENDELEEV'S PERIODIC TABLE Base chemical properties of elements. Like : reaction with O2, H2 & X2 Mendeleev's Periodic Law Physical & chemical properties of elements are periodic function of their atomic weight
Prout's Hypothesis Dobernier's triad Newlands law of octave
8 Groups & 7 period
Lother meyer curve
Left some vacant position for some elements. eka-boron - Sc eka-Aluminium-Ga
MOSELEY x-ray EXPERIMENT zµn Modern Periodic law Physical & chemical properties of the elements are periodic function of their atomic numbers. Introduced zero group for Nobel gases.
eka-managanse-Tc eka-silicon-Ge
(a) Bohr classification
(iv) Inert gases :
(i)
18 group He, Ne, Ar, Kr, Xe Rn Do not use any electron during chemical combination (b) On the basis of conductivity
Normal / representative elements s & p block (except inert gas) 1-2 1—5 ns np ; use electrons only valence shell during chemical combination. (ii) Transition elements d-block : use electrons of n shell as well as (n—1) shell during chemical combination. Zn, Cd & Hg are not transitional elements. (iii) Inner transition elements f-block : use electrons of n shell (n-1) shell and (n-2) shell
Metal ®conductor Metalloid ®semi-conductor Non-metals®Non-conductor (c) On the basis of physical state Solid (rest) Liquid (6): Br, Ga, Hg, Uub, Cs, Fr Gas (11): He, Ne, Ar, Kr, Xe, ln, F, Cl, O, N, H
POSITION OF ELEMENTS IN PERIODIC TABLE Period : Highest number of shell, which contain electron. Block : Highest energy sub-shell which contain electron. ns < (n-2) f < (n-1)d < np Group No. : depends on block (a) s-block : Number of ns electron's (b) p-block : Number of np electron's +12 (c) d-block : Number of ns + (n-1)d electron's rd
(d) f-block : 3 or IIIB group.
54
Eg . : Atomic n umber 5 3: [Kr] 5s 2 10 5 4d 5p Period-5 Block-P Group- 1 2+5= 17
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DEVELOPMENT OF PERIODIC TABLE
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Chemistry HandBook
CH APTER
ALLEN
PERIODICITY
SCREENING EFFECT / SHIELDING EFFECT
Repetition of properties after regular
H
interval is known as periodicity and these properties are known as periodic properties. 1. Effective nuclear charge (Z eff) 2. Atomic Radius 3. Ionisation potential 4. Electron affinity 5. Electro negativity
Repulsive force applied by inner electron on a particular electron / last electron / tested electron. Calculation of screening (s)- by Slater's Rule. Z s by test electron = 0.00 Z s by rest of valence electron = 0.35 Z s by (n-1) s,p ®0.85 Z s by (n-2) or inner electrons = 1.0 Varation of s ® along the periodic & down the group increases. Order of s : s > p > d > f
ATOMIC RADIUS Distance between centre of nucleus to outermost electron.
H Effective nuclear charge (Zeff) Zeff = Z—s
PERIODIC TRENDS
Accurate value of atomic radius cannot be measured. We measure internuclear distance and assume half of it as atomic radii.
group T ¯ B AR
On the basis of type of bond atomic radii is of following type : Single bonded species rmetallic
rcovalent A
A
A
rcov =
dA—A 2
A
A
rmetallic=
rvanderwaal
dA—A 2
* Al ; Ga : Transition Contraction
rvanderwaal's = dA—A 2
* 4d ; 5d : Lanthanide Contraction d-block
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E
ION
IC
RA D
» » » » » » » » » » »
1 Zeff
1 bond strength
(b) Different series (generally) — — — — — 2e < 10e < 18e f (applicable in neighbor atom)
5 6
th
Factor 5 & 6 applicable upto 4 period only Be > B Sb < Te N>O
PER IODICITY
Period IP L-R group T ¯ B IP¯
OF
IP
Metallic character µ
1 IP
Reactivity of metal µ
1 IP
Electro+ve character µ
1 IP
Reducing naturer µ
1 IP
atom
anion -energy
Amount of energy released or absorb when an electron added to neutral gaseous atom. -
x(g) + e ® x (g) —
—
No. of valance e = consider successive IP highest jump in successive IP indicate nobel gas configuration if it is 'a' then no. of valence e— — valence e = a—1 Consider successive IP STABILITY OF (a) If DIP ® < 11 eV higher o.s. stable STATE TION OXIDA DIP ® > 16 eV lower o.s. stable
56
+e—
Generally Exothermic If we measure energy in term of energy change it is known as electron gain enthalpy. DHeg = final state - initial state (anion) (atom)
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APPLICATION
E
FACTORS E.A. µ Zeff E.A. µ 1 size Electron configu ration : Stable valen ce sh ell configuratio n of electron gaining would be a endothermic higher the stability of configuration higher endother mic process of elec tron gaining or der Be N Ne 2s 2 2s22p 3 2s 22p 6 order Ne < Be < N of EA max endo least endo
re than one e ; these When an atom gain mo ssive electrons and ce suc s K/a electrons are cessive electron affinity. their energy is K/as suc II — I 2— +e — x — x ener gy x + e energy —
EA 2
EA 1
othermic due to EA2 or higher always end incoming electron. & on repulsion between ani
in p-block B ^ Al
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PERIODICITY
®EA e DHeq -v ¯ EA¯ DHeq -ve ¯
EXCEPTIONAL POINT
ELECTRONEGATIVITITY
EA of 2nd period < 3rd period
Tendency of an atom to attract shared pair of electron towards itself in bonded state is known as electronegativity. ® Relative Phenomenon. ® Unit less property. ® For Nobel gas we consider EN = zero.
C ^ Si
N ^ P
O ^ S
F ^ Cl
Maximum EA 'Cl' O has least in it's group.
RELATIONSHIP BETWEEN IP & EA +e ; EA —
—
m
+
IP of M = EA of M+
x
+e ; EA —
EA of x = IP of x—
E
Non-polar bond DEN = 0 Polar bond
DEN ¹ 0
Exception : Zn < Cd < Hg Ga < In < Tl
CT
RO
A E L E PP L I C
Period L-R EN
Bond & Bond properties
DEN® Bond polarity ¯ Bond length ¯ ¯ Bond strength ¯ Ionic character
Bond length - Sehumaker stevension formula = d A-B = r A + rB - 0.09 × DEN
O XIDES & HYDROXIDES
N ATURE OF C OMPOUNDS
% age ionic character : Hennay -Smith formula = 16 × DEN + 3.5 (DEN) Acidic character µEN 1 Basic character µ EN
2
Electro negativity ® Acidic character of oxide Basic character of oxide ¯ s-block hydride - Metallic hydride, basic character µ size P-block hydride - Non metallic hydride, acidic character µ size
HYDRIDES
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PERIODIC TRENDS
group T ¯ B EN¯
—
x
-e ; IP
AT IO N O NE GA F T IV I TY
-e ; IP —
M
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CHEMICAL BONDING CHEMICAL BONDING Force of attraction which holds two or more than two species together is known as bond. H—H
H2O
REASON To attain the state of maximum stability, species have tendency of bonding.
+
H2O
Na
Cl
—
CLASSIFICATION OF BONDS On the basis of type of species getting bonded bonds can be classify into following categories. BOND Intermolecular force between molecules weak bond 2-40 kJ/mol
Interatomic bond between two atom strong bond 200 - 400 kJ/mol
Non-metal + Non-metal - covalent bond H-bond
Non-metal + Metal - Ionic bond
1. Ion-dipole 2. Dipole-Dipole 3. Ion-Induced dipole 4. Dipole-Induced dipole 5. London force
Metal + Metal - Metallic bond Coordination bond is type of covalent bond
Formation of covalent bond explained by three theories. Valence Bond Theory
Molecular Orbital Theory
LEWIS OCTET THEORY
VALENCE BOND THEORY
As per Lewis Octet Theory Bonding for Stability Stability by achieving Nobel gas configuration.
Atoms undergoes sharing of electron. Sharing of electron leads to the formation of covalent bond.
VALENCE B OND THEORY Sharing
60
Equal sharing - Covalent Bond Unequal sharing- Coordinate Bond
H2
Cl2
O2
HNO3
H H
Cl Cl
O O
H—O—N
H—H
Cl—Cl
O=O
O O
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Lewis Octet Theory
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EXCEPTION (a) electron deficient Central atom: No. of electron < 8 BeH2 BF3, BCl3, BBr3, BI3 AlCl3, AlBr3, AlI3
OF
OCTET RULE
(b) electron rich Central atom: No. of electron > 8 PCl5 , IF7 SF6, XeF2
(c) odd electron species Central atom : has odd electron NO, NO2, ClO2 ClO3
CO-ORDINATE BOND (DATIVE BOND) In this type of bond, shared pair of electron donates by one species but shared by both For this type of sharing One species - must have lone pair - act as donar known as Lewis base - acquire +ve charge. Another species - must have vacant orbital act as acceptor known as Lewis acid - acquire -ve charge.
LB
LA
+
N
y
+
+
H
rl
H H H
ila
N+H
+
m
H H H
Si
Eg.
H2O + H
H3O
+
+
N2H4+H
N2H5
AlCl3 + AlCl3
Al2Cl6
Donor atom follow octet rule
MODERN APPROACH OF COVALENT BOND Consider wave mechanical model of atom means electron has dual nature; wave nature as well as particle nature considered by these theories, there are two theories in this approach. 1. Valence Bond Theory
VALENCE BOND THEORY Proposed by Heitler & London as per VBT bonding takes place for attaining stability. 1 Stability µ Potential energy
2. Molecular Orbital Theory Only those orbitals of valence shell can exhibit overlapping which has Unpaired electron
attraction > repulsion
Opposite spin
E
native state of atom
energy
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+ve
AF > RF
-ve
AF > RF
Attraction=Repulsion [Min. potential energy state]
Strength of Covalent Bond Strength of covalent bond µ extent of overlapping. 1. NATURE OF ORBITALS (a) No. of shell : lower the number of shell higher overlapping.
distance
Bond formation is an exothermic process. During this process some extent of electron cloud merge into each other; this part is known as overlapped region & this process is known as overlapping. Atom
For example H—Cl bond form by overlapping of 1s - 3p orbitals. 1 H® 1s 2 2 6 2 5 Cl® 1s 2s 2p 3s 3p
Nucleus Shell - subshell - orbital - electron - cloud
Bond Strength µ
1 /size of orbitals No. of shell
1-1 > 1-2 > 2-2 > 2-3
Exception : Cl2 > Br2 > F2 > I2 O—O < S—S N—N < P—P
due to lp-lp repulsion
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(b) Type of Sub-shell Valence shell contain subshell s & p s-non-directional p-directional
s-s < s-p < p-p
Directional orbital has higher extent of overlapping
** This factor is applicable when number of shell is same otherwise shell factor prominent 2s - 2s < 2s-2p < 2p-2p sub-shell factor 1s - 1s > 1s-2s > 1s-3s shell factor
2. P ATTERN OF OVERLAPPING (a) Axial overlapping : Along the internuclear axis; form sigma (s) bond, strong bond.
(b) Co-lateral overlapping Side wise overlapping has less extent of overlapping form p- bond Weak bond
s-s
p-p overlapping
Internuclear axis pp-pp pi-bond
s-p
p-d overlapping
p-p
pp-dp pi bond
In case of multiple bond between two atom one bond is sigma and rest are pi-bonds. VBT was not able to define geometry of molecule therefore a new concept came into existence known as hybridisation.
HYBRIDISATION Intermixing of atomic orbitals and formation of new orbital, these orbitals are known as hybrid orbital and this concept is known as hybridisation. It is hypothetical concept. Only those orbitals can participate in hybridisation which has slight difference in energy.
S.No. Type of orbital
62
No. of hybrid orbital
1. 2. 3.
one s + one p one s + two p one s + three p
2; sp 2 3; sp 3 4; sp
4.
one s + three p + one d
5; sp d
5.
one s + three p + two d
6; sp d
6.
one s + three p + three d
7; sp d
3D orientation Linear Triangular Tetrahedral
Example BeH2, BeCl2 BCl3, BF3 CH4, CCl4
3
Triangular bipyramidal
PCl5
3 2
Octahedral /Square bipyramidal
SF6
Pentagonal bipyramidal
IF7
3 3
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No. of hybrid orbitals : No. of atomic orbitals participate in intermixing Hybrid orbitals oriented at maximum possible distance three dimensionally. Type of hybridisation.
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VALENCE SHELL ELECTRON PAIR REPULSION THEORY
o o o
Given by Nyholm & Gillespie to define shape of molecule.
o
Order of replusion :
Shape of molecule define on the basis of electron pairs orientation present on central atom. Electron pairs present on central atom repel each other therefore these electron pair occupy such position on central atom; where they experience minimum repulsion at maximum possible distance three dimensionally. lp-lp > lp-bp > bp-bp
mb-mb > mb-sb > sb-sb
TYPE OF HYBRIDISATION & POSSIBLE STRUCTURE No. of B.P.
Type of Hybridisation
No. of L.P.
Shape
1. sp-hybridisation
2
-
Linear
BeF2, CO2, CS 2,BeCl2
2. (a) sp2-hybridisation 2 (b) sp -hybridisation
3 2
1
Trigonal planar V-shape,Angular
BF3, AlCl3, BeF3— — NO2 , SO2, O3
4 3 2
0 1 2
Tetrahedral Pyramidal V-shape Angular
CH4, CCl 4, PCl4 , ClO4 , NH4 , BF 4 , SO4 , AlCl4 NH3, PF 3, ClO3—, H 3O +, PCl 3, XeO3,N(CH 3) 3, CH 3— H2O, H2S, NH2— + OF2, Cl2O, SF2, I3
4. (a)sp d-hybridisation (b) sp3d-hybridisation
5 4
1
(c) sp3d-hybridisation (d) sp 3d-hybridisation
3 2
2 3
Trigonal bipyramidal See-Saw, folded square distorted tetrahedral almost T-shape Linear
PCl5, SOF 4, AsF 5 SF4, PF4—, AsF4— SbF4—, XeO2F2 ClF3, ICl3 I3—, Br3—, ICl2—, ClF 2—, XeF2
5. (a) sp3d2-hybridisation (b) sp3d2-hybridisation 3 2 (c) sp d -hybridisation
6 5 4
1 2
Square bipyramidal/octahedral Square pyramidal/distorted octahedral Square planar
PCl 6—, SF 6 XeOF 4, ClF5, SF5—, XeF5+ XeF 4
6. (a) sp d -hybridisation (b) sp3d3-hybridisation
7 6
1
(c) sp3d3-hybridisation
5
2
Pentagonal bipyramidal IF 7 Pentagonal pyramidal/ XeF 6 distorted octahedral /capped octahedral Pentagonal planar XeF 5—
3
3. (a) sp -hybridisation (b) sp3-hybridisation (c) sp3-hybridisation 3
3 3
DIPOLE MOMENT Measurement of Polarity in a molecule m = q ×d
debye = esu-cm 1D = 10—18 esu.cm
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(A) Identification of polar or Non-polar molecule. Molecule : Symmetrical distribution of electron cloud- Non-polar. Molecule : Unsymmetrical distribution of electron cloud- Polar.
E
Examples
Diatomic Molecule (a) Homoatomic D EN = 0 ® m = 0 ® Non-polar H2, F 2, Cl2, N2 etc. (b) Heteroatomic D EN ¹ 0 ® m net= 0 ® polar HF > HCl > HBr > HI Polyatomic molecule : m R ® Vector sum of bond moment m R ® m 12+m 22+2m 1m 2 cosq Important Order NH3 > NI3 > NBr3 > NCl3 > NF3 NH3>SbH3>AsH3 > PH3 H2O > H2S CH3Cl > CH3F > CH3Br > CH3I CH3Cl > CH2Cl2 > CHCl3 > CCl 4
+
—
+
-1
-2
—
Applications Predict shape and polarity of molecule Symmetrical geometry ® m =0 ® non-polar Unsymmetrical geometry ® m ¹ 0 ® polar Distinguish between cis & trans form H H
C
CH3
C CH3
H
C
CH3
CH3 C H
maleic acid m¹ 0
fumaric acid m= 0
Dipole moment in Aromatic Compounds Cl
Cl
Cl
Cl Cl Cl Orthodichloro benzene
metadichloro benzene
mµ
paradichloro benzene
1 bond angle
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HYDROGEN BONDING Electrostatic force of attraction between hydrogen & highly electronegative atoms. It is dipole-dipole type of attraction Hydrogen should be covalently bonded with highly electronegative elements. Like : F,O & N. Strength of H-bond µ Electronegativity of electronegative elements Strength Intermolecular H-bond > Intramolecular H-bond Intramolecular H-bonding takes place in ortho derivatives only.
Type of Hydrogen Bond Intermolecular
Intramolecular
E X AM P L ES
Between molecule
Applications of H-bonding Physical State (densile nature) µ H-bond Melting Point (mp) µ H-bond Boiling Point (bp) µ H-bond Viscosity µ H-bond Surface Tension µ H-bond Volatility µ 1/H-bond Vapour Pressure µ 1/H-bond
Within molecule It is not an intermolecular force
H2O is liquid while H2S is gas. HF is liquid while HCl is gas. Viscosity & Surface Tension
CH 2—OH CH—OH > CH2 OH
CH2—OH CH 2—OH
>CH 3—OH
Specific
Solubility in H2O : Any organic compound which get dissolve in H2O, it is due to H-bonding.
Examples
Association of Molecule : KHF2 is possible but not KHCl2 it is due to K [F -----H—F]
+
—
ion dipole type h-bond
MOLECULAR ORBITAL THEORY Given by Hund & Mulliken given Given To explain : O2 : Paramagnetic nature. Existence of species like H2+, H2—
As per MOT bond form by combination of atomic orbitals & interference of electron wave interference of electron wave leads to formation of molecular orbitals.
atomic orbitals - electron waves - interference Constructive Interference same phase wave - bonding molecular orbital (BMO)
constructive interference destructive interference
Destructive Interference opposite phase wave - anti-bonding molecular orbital (ABMO)
All atomic orbitals of an atom participate in combination and form molecular orbitals with atomic orbitals of another atom. Energy level of molecular orbital s1s s*1s s2s s*2s p2px= p2py s2pz p*2px = p*2py s*2p z Total electron SrCl2>BaCl2
cation size polarisation¯ covalent character¯
Covalent character
(ii) SF2 < SF4 < SF6 -1
(2) Polarisation µ
-3
Covalent character (anion charge)
(iii) LiF < Li2O < Li3N
SOLUBILITY For s-block same group cation Lattice Energy /Hydration Energy IA
(i) If common ion smaller 1 µ size solubility µ LE
IIA (ii) If common ion larger
IA
—2
—
—
—2
—
—
For all
—2
O , OH , F , SO4 , CO O , OH , F
—2 3
Eg. (i) PbF2 > PbCl2 > PbCl2 > PbI2 (Anion size, cov. char., solubility ¯)
—
—
— 4
Br , I , ClO
(ii) Fe+2(OH)2 > Fe+3(OH)3 (+) charge, PP, CC , solubility ¯
CO —2, SO4—2, NO3—, Br—, IIA — 3 —2 —2 — I , S , S2O3 , Cl Eg. (i) Li2CO 3 < Na 2CO3 < K2CO3 < Rb2CO3 < Cs2CO 3 common ion smaller (CO3—2) solubilityµ
1 LE
(ii) BeCO3 > MgCO3 > CaCO3 > SrCO3 > BaCO3 common ion larger (CO
) solubility µ HE
—2 3
(iii) BeSO4 > MgSO4 > CaSO4 > SrSO4 > BaSO4 common ion SO4—2 larger solubility µ HE
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1 cov. char.
1 ionic char [CCl4, benzene, ether, alcohol, acetone]
solubility µ HE
E
solubility µ
(iii) ZnCl2 > CdCl2 > HgCl2 Zeff, PP, CC , solubility ¯ (iv) Na2SO4 > MgSO4 (+)charge, PP, CC , solubility ¯ (v) ZnCl2 > CdCl2 > HgCl2 Zeff, PP, CC , solubility ¯ (vi) NaCl > CuCl PP, CC , solubility ¯ (vii) AgF > AgCl > AgBr > AgI Anionic Size, PP , CC, solubility ¯
IMPORTANT NOTES
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THERMAL STABILITY/THERMAL DECOMPOSITION For Momoatomic Anions
For Polyatomic Anions
(X–, H–, O–2, etc.)
–2
(CO3 , HCO3–1, SO4–2, OH –1, O2–2, O2–1 etc.)
In a gp : T.S. µ L.E. µ 1 Size
T.S. µ
1 µ size of cation Polarisation
In a Pd : T.S. µ D EN eg. : 1. LiF > NaF > KF > RbF > CsF
eg. : 1. Li2CO3 < Na 2CO3 NaH > KH > RbH > CsH
2. BeSO4 < MgSO4
Inter
More mass
Intra
>
Vanderwaal
Less mass • If mass is same MP µ Polarity of molecule
>
H-Bond
Molecular solid
C HAP TE R
MP & BP µ
MP µ
MP µ L.E.
IIA
Large anion
Ionic solid
M.P. and B.P. (General order)
With small anion
MP µ L.E.
IA
For p & d - block metal compound
Covalent solid B4C, SiC, Diamond, Graphite etc.
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s-BLOCK ELEMENTS Chemical property of alkali metal & alkaline earth metal
i
Order of metallic or Ionic radii%
i
Reaction with air (N2 & O2) All forms their normal oxide & nitrides. Exception : Nitride of Na, K, Rb, Cs is not possible.
i
Reaction with O2 & Excess of air Li – normal oxide Be – normal oxide Na – peroxide Mg – normal oxide K – super oxide Ca – peroxide Rb – super oxide Sr – peroxide Cs – super oxide Ba – peroxide
i
Reaction with H 2 O : All form their hydroxide & H2 gas Order of basic strength : Cs2O > Rb2O > K2O > Na2O > Li2O BaO > SrO > CaO > MgO > BeO CsOH > RbOH > KOH > NaOH > LiOH Ba(OH)2>Sr(OH2)>Ca(OH)2>Mg(OH)2> Be(OH)2 Exception : Be does not react with H2O , Mg reacts with hot water. Order of reactivity with H2O in IA and IIA group Cs > Rb > K > Na > Li Ba > Sr > Ca > Mg > Be
i
CO3–2 & SO4–2 salt of Na, K, Rb and Cs only are not decomposed on heating due to large size and weak polarising power.
i
In nitrate salts
Cs > Rb > K > Ba > Sr > Ca > Na > Mg > Li > Be i
i
Order of density : Ist A
Cs > Rb > Na > K > Li
IInd A
Ba > Sr > Be > Mg > Ca
Order of MP & BP% Ist A
Li > Na > K > Rb > Cs
II A
Be > Ca > Sr > Ba > Mg
nd
i
i
i
i
Order of hydration in cation : IA
Li+ > Na+ > K+ > Rb+ > Cs+
IIA
Be+2 > Mg+2 > Ca+2 > Sr+2 > Ba+2
Order of conductivity of cations in polar solvent IA
Cs+ > Rb+ > K+ > Na+ > Li+
IIA
Ba+2 > Sr+2 > Ca+2 > Mg+2 > Be+2
Order of conductivity in non-polar solvent IA
Li+ > Na+ > K+ > Rb+ > Cs+
IIA
Be+2 > Mg+2 > Ca+2 > Sr+2 > Ba +2
Colour of s-block metal in flame test Li
Crimson red
Na
Golden yellow
K
Pale violet
Rb
D ® Na/K/Rb/CsNO2 + 2Na/K/Rb/CsNO3 ¾¾¾¾ 800° C >
Reddish violet
Cs
Sky blue
D
® Na/K/Rb/Cs O+N + 800° C or 2Na/K/Rb/CsNO3¾¾¾¾ 2 2 800° C
H2S > H2Se > H2Te Bond angle : 104.5° 92.5° 91° 90° (all sp3 hybridised)
l
SO3 is a gas, sp2 hybridised and planar in nature. O é1pp - pp ù S ê ú ë 2 pp - d p û O O O O O
S l
S
S
O O O O O O In solid state it exists as a cyclic trimer (SO3)3, a-form or as linear cross-linked sheets, b-form. O O sp3 S sp3 S = O bond Þ 6 O O S - O - S bond Þ 3 O S S O O O O a-form
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OXYGEN (O2)
OZONE (O3)
p Preparation : By action of heat on oxygen rich compounds : l From oxides : D 2Hg O ¾¾® 2Hg + O2 l From peroxides : 2Na2O2 + 2H2O ¾® O2 + 4NaOH D 2BaO2 ¾¾® 2BaO + O2 l From decomposition of certain compounds D 2KClO3 ¾¾¾® 2KCl + 3O2 MnO2
2KNO3 ¾® 2KNO2 + 3O2 p Chemical properties : On heating it combines directly with metals and non-metals, causing oxidation. C + O2 ¾® CO2 S + O2 ¾® SO2 Pb + O2 ¾® PbO2 2CH3OH + O2 ¾® 2HCHO + 2H2O p Uses % l When mixed with He or CO2, it is used for artificial respiration. l In welding and cutting. l As a fuel in rockets.
p Preparation : l Lab method : 3O2 2O3 (DH = +ve) Electric discharge
p Properties : Pale blue gas with characteristic strong smell, slightly soluble in water but more soluble in turpentine oil or glacial acetic acid. l Decomposition: 573K 2O3 ¾¾¾ ® 3O2 + 68kcal
l Oxidising action: O3 ¾® O2 + O PbS + 4O ¾® PbSO4 l Reducing action: H2O2 + O3 ¾® H2O +2O2 BaO2 + O3 ¾® BaO + 2O2 p Ozone reaction: (i) Tailing of Mercury : 2Hg + O2 ¾® Hg2O + O2 (ii) Estimation of Ozone : 2KI + H2O + O3 ¾® O2 + I2 + KOH (Na2 S2O3 .5H2O) ® 2NaI + Na2S 4O6 I2 ¾¾¾¾¾¾
p Uses : l Bleaching ivory, flower, delicate fabrics, etc. l As germicide and disinfectant, for sterilising water. l Manufacture of KMnO4 and artificial silk.
SULPHUR DIOXIDE (SO2) p
Preparation %
p
D By heating sulphur in air. S + O2 ¾¾ ® SO2 l Lab method : By heating Cu with conc. H2SO4. Cu + 2H2SO4 ¾® CuSO4 + SO2 + 2H2O Properties : l As reducing agent % SO2 + Cl2 + 2H2O ¾® H2SO4 + 2HCl 2KMnO4 + 5SO2 + 2H2O ¾® K2SO4 + 2MnSO4 + 2H2SO4 l As oxidising agent : 2H2S + SO2 ¾® 2H2O + 3S¯ l Bleaching action : Its bleaching action is due to reduction. SO2 + 2H2O ¾® H2SO4 + 2H Coloured matter + H ¾® Colourless matter.
2(Nascent hydrogen)
p
86
Uses : l In the manufacture of sulphuric acid,sulphites and hydrogen sulphide. l As a disinfectant and fumigate. l For bleaching delicate articles.
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SULPHURIC ACID (H2SO4)
It is also known as oil of vitriol and king of chemicals. p Manufacture of sulphuric acid : l Lead chamber process : The various steps involved are : l Contact process : Step involved (a) Production of SO2
GROUP 17 ELEMENTS p Reactivity : All halogens are chemically very reactive elements. This is due to their low dissociation energy and high EN. Fluorine is the most reactive and iodine is the least reactive halogen. p Oxidising power : F is the most oxidising element due to high hydration enthalpy. F2 > Cl2 > Br2 > I2.
S + O2 ¾® SO2 M.Sulphide + O2 ¾® SO2 (b) Conversion of SO2 to SO3 SO2 O2 SO3 V2O5
(c) SO3 + H2SO4 ¾® H2S2O7 oleum H2S2O7 +H2O ¾® 2H2SO4 p Properties : Its specific gravity is 1.8 and it is 98% by weight.
HYDROGEN HALIDES Bond strength, bond length and thermal stability : • Since size of halogen atom increases from F to I down the group, bond length of H – X bond increases down the group. \ reactivity and acidic character . HF < HCl < HBr < HI. • Bond strength order HF > HCl > HBr > HI. • Bond energy order
l It is strong dibasic acid. H2SO4 2H+ + SO42– l It acts as an oxidising agent. H2SO4 ¾® H2O + SO2 + O
HF > HCl > HBr > HI. REDUCING CHARACTER : The reducing character of hydrogen halides increases down the group as HF < HCl < HBr < HI.
l Non metals are oxidised to their oxides and metals to the corresponding sulphates. C + 2O ¾® CO2
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l Dehydrating agent : It is strongly dehydrating in nature.
E
H2 SO 4 C12H22O11 ¾¾¾¾ ® 12C + 11H2O
(Charring of sugar) p Uses : l In lead storage batteries. l In manufacture of paints and pigments. l In metallurgy for electrolytic refining of metals.
2HX ¾® H2 + X2 A less thermally stable compound has more tendency to release hydrogen easily and show greater reducing property. OXIDES : F ¾® O2F2, OF2 Cl ¾® Cl2O, Cl2O3, Cl2O5, Cl2O7, Cl2O2, ClO3 Br ¾® Br2O, Br2O7, Br2O5 I ¾® I2O, I2O7, I2O5, I4O9 (Ionic) Stability : I > Cl > Br (Middle row anormaly)
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CHLORINE (Cl2) p Preparation : By oxidation of conc. HCl. PbO2 + 4HCl ¾® PbCl2 + 2H2O + Cl2 2KMnO4+16HCl ® 2KCl+2MnCl2+8H2O+5Cl2 p Manufacture : Weldon's process : By heating pyrolusite with conc. HCl. MnO2 + 4HCl ¾® MnCl2 + 2H2O + Cl2 p Properties : It is a yellowish green gas, poisonous in nature, soluble in water. Its aqueous solution is known as chlorine water which on careful cooling gives chlorine hydrate Cl2.8H2O. Bleaching action and oxidising property (i) Cl2 + H2O ¾® HOCl + HCl HOCl ¾® HCl + [O] Coloured matter + nascent [O] ® Colourless matter The bleaching action of chlorine is permanent and is due to its oxidising nature. (ii) SO2 + Cl2 + 2H2O ¾® H2SO4 + 2HCl Oxidising behaviour of Cl2 Cl2 Fe+2
Fe+3
–2
SO4
I2
HIO3
Br–/I–
Br2/I2
SO3
–2
Cl– l Addition reactions : SO2 + Cl2 ¾® SO2Cl2 CO + Cl2 ¾® COCl2 p USES : l It is used as a (i) bleaching agent (ii) disinfectant (iii) in the manufacture of CHCl3, CCl4, DDT, bleaching powder, poisonous gas phosgene (COCl2), tear gas (CCl3NO2) and mustard gas (ClC2H4SC2H4Cl).
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HYDROCHLORIC ACID, (HCl) p Preparation : By dissolving hydrogen chloride gas in water. Hydrogen chloride gas required in turn can be prepared by the following methods: l By the direct combination of hydrogen and chlorine. Sunlight H2(g) + Cl2(g) ¾¾¾¾ ® 2HCl(g)
l Hydrogen chloride gas can also be obtained by burning hydrogen in chlorine. l By heating halid with conc. H2SO4 NaCl + H2SO4 ¾® NaHSO4 + HCl NaHSO4 + NaCl ¾® Na2SO4 + HCl Imp. Points : l HCl cannot be dried by P2O5 or quick lime. CaO + 2HCl ¾® CaCl2 + H2 P4O10 + 3HCl ¾® POCl3 + 3HPO3 l Reducing property : HCl is a strong reducing agent. MnO2 + 4HCl ¾® MnCl2 + 2H2O + Cl2 p Uses : l In the production of dyes, paints, photographic chemicals, etc. l Used in the preparation of chlorides, chlorine, aquaregia, etc. l Used as a laboratory reagent.
INTERHALOGEN COMPOUNDS p These compounds are regarded as halides of more electropositive (i.e. less elecronegative) halogens. p Types of interhalogen compound : AB type : ClF, BrF, BrCl, ICl, IBr AB3 type : ClF3, BrF3, ICl3 AB5 type : BrF5, IF5 AB7 type : IF7 USES OF INERT GASES : (1) He is non-inflammable and light gas, so it is used in filling balloons for meteorological observations. (2) He is used in gas cooled nuclear reactors. (3) Liquid He is used as cryogenic agent. (4) He is used to produce powerful superconducting magnets. (5) Ne is used in discharge tubes. (6) Ar is used as inert atmosphere in metallurgical process. (7) Xenon and Krypton are used in light bulbs designed for special purposes. (8) He is used as a diluent for oxygen in modern diving apparatus due to its very low solubility in blood.
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COORDINATION CHEMISTRY Complex Compound Representation of coordination compound K4 [Fe(CN)6]
C.N.
(coordination no.)
Ionisation sphere / Counter Ion Coordination sphere / Entity Central metal atom/ion Ligand
LIGANDS Species which donate lone pair/ electron pair is called as ligand, on the basis of the number of e pairs available for donation; ligands are classified as LIGANDS On the basis of denticity
On the basis of charge Neutral Anionic Cationic
Monodentate Bidentate Polydentate Flexidentate Ambidentate
Classical
Non-classical
p e— donating ligand
— Eg. CH2=CH2, COO | COO—
These are the polydentate ligands LIGAND
AMBIDENTATE
which bind to the central metal to form a puckered ring structure. Chelation leads to extra stability, for example, EDTA (ethylene diamine tetra acetate).
FLEXIDENTATE LIGANDS
Exhibit variable denticity.
2—
2—
Eg. SO4 , CO3 , EDTA
4—
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Bidentate : Contain two donor sites.
They can change their donor atom (side) but not denticity. Eg. : — — — –CN , and –NC , –SCN — — — and –NCS , NO2 and ONO , — — –OCN and NCO . These ligands are responsible for linkage isomerism.
90
p acid ligand
Monodentate : have only one donor sites. Eg. H2O, NH3
LIGAND
of denticity
lp donation/accepting e—s
CHELATING
On the basis
On the basis of
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BONDING
IN
C OORDINATION C HEMISTRY BONDING
Werner Theory
Valence Bond Theory
Crystal Field Theory
WERNER'S THEORY Metal in a complex shows two type of valences - Primary & secondary. Primary valency It is oxidation no. of metal. It is variable Satisfied by anions (present in coordination or ionisable sphere). Ionisable Ionic \ nondirectional Represented by dotted line in Werner structure.
COCl3.4NH3
Eg.
Molecular formula
[Co(NH3)4Cl2]Cl
H 3N
Secondary Valency It is coordination number It is non variable. Satisfied by ligands (present in coordination sphere) Non ionisable Directional \ decide geometry of complex ion. Represented by solid lines in Werner structure.
NH3 Cl Co
complex formula
H3N
Cl
3 dotted line shows - Primary Valence 6 solid line shows - Secondary Valence
NH3 Cl
Werner structure
VALENCE BOND THEORY Central metal atom /ion & ligand come close to each other ligand donate lone pair & CMA provide vacant orbital. There is hybridisation of atomic orbitals provided by central atom to ligands. Type of Orbitals participating in intermixing depend upon two factors. (a) Availability of orbitals (b) Nature of ligand Coorination No. 2 3
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5 6
Type of hybrid orbital sp 2 sp 2 square planar -dsp 3 tetrahedral -sp 3 dsp sp3d 3 2 sp d - outer orbital complex (high spin) 2 3 d sp - inner orbital complex (low spin)
Eg. : 2— 3 [NiCl4] sp -----Tetrahedral 2— 2 [Ni(CN)4] dsp ----- Square planar 3 [Ni(CO)4] sp -----Tetrahedral 2+ 3 [Zn(NH3)4] sp -----Tetrahedral 2+ 2 [Cu(NH3) 4] dsp -----Square planar Coordination No. 6 : Example d2sp3 [Fe(CN)6]4— 2 3 3— d sp [Fe(CN)6] 3+ 2 3 d sp [Co(NH3)6] 2+ 3 2 [Ni(H2O)6] sp d
VALENCE BOND THEORY m m
2
3
If the complex is formed by the use of inner d-orbitals for hybridisation (d sp ), it is called inner orbital complex. 3 2 If the complex is formed by the use of outer d-orbitals for hybridisation (sp d ), it is called an outer orbital 3— complex. Such a complex is also called as high spin complex e.g. [CoF6] .
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CRYSTAL FIELD T HEORY (CFT) CRYSTAL FIELD SPLITTING m
The splitting of five degenerate d-orbitals of the metal into different sets of
m
orbitals having different energies in the presence of electrostatic field of 2 2 2 ligands is called crystal field splitting. egset – dx –y , dz t2g set– dxy, dyz, dxz Crystal field splitting energy, (DO for octahedral structure and Dt =4/9D0 tetrahedral structure) is the difference between the various sets of energy
m
levels formed by crystal field splitting. Weak field ligands are those ligands which cause a small degree of crystal field —
m
—
—
—
—
ISOMERISM
Hydrate
2—
splitting e.g. I , Br , Cl , F , OH , C2O4 , H2O, etc. Strong field ligands are those ligands which cause a high degree of splitting e.g. CO, CN , NO , etc. Spectrochemical series — — — — — — 2— I < Br < Cl < NO3 < F < OH < ox < H2O < py ~ en < dipy < o-phen < –
—
m m m
—
Geometrical
Optical
Linkage Coordination
–
2
m
Stereo
Structural Ionisation
—
NO2 < CN < CO. ( C and N donar act as SFL except N3 ) For 4d & 5d element all ligands acts as S.F.L. +3 –2 With CO (OX) , H2O acts as S.F.L. +2 +2 With Fe & Mn , NH3 act as W.F.L.
Important Point : Extent of synergic bonding
M–C B.L.
C–O B.L.
[M(CO)n]
–
Max.
Min.
Max.
[M(CO)n]
+
Min.
Max.
Min.
Ionisation isomerism : Same molecular formula (b) but gives different ionisable species. (Only anionic)
Hydrate isomerism : Same molecular formula but different number of water molecules associated with central metal. (a) [Cr(H2O)6 ]Cl3
(a) [Pt(NH4)4 Cl2]Br2 PtCl2Br2.4NH3
CrCl3.6H2O (b) [Pt(NH3)4 Br2]Cl2
(c)
Linkage isomerism : Structural isomerism shown by (d) ambidentable ligands
(NO ,CSN ,CN ,CNO etc ) – 2
[Fe(NH3) 5(SCN)]
92
–
2+
–
–
[Fe(NH3)5(NCS)]2+
(b) [Cr(H2O)5Cl]Cl2.H2O (c) [Cr(H2O)4Cl2]Cl.2H2O
Coordination isomerism : Isomers having both anion and cation as complex entity. Can inter change position of ligands as well as metal. [Cr(NH3)6][Co(CN)6]
[Co(NH3)6][Cr(CN)6]
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STRUCTURAL (a)
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STEREOISOMERISM Sq. planar complex with symmetrical bidentate ligand. Eg. No GI Sq. planar complex can exhibit GI only in two types
M(AB)2 M(AB)(CD)
* On increasing number of one type of ligand total number of geometrical isomers decreases. Whenever same type of ligand placed at 180° it will not show O.I.
[M(AA)2a2] type of complex have two GI (cis & trans) * [M(AA)2a2] type of complex gives three stereo isomer : (1) cis (2) trans (3) mirror image of cis
O RGANOMETALLIC COMPOUDS Compounds in which the less E.N. (Ge, Sb, B, Si, P, As) central metal atoms are bonded directly to carbon atoms are called organometallic compounds. m s - bo nd ed c om p ound s nontransition elements.
fo r m ed
IUPAC nomenclature of complex compounds : (A)
by
Common name of normal cation (without numeral prefix) + name of ligands (with numeral prefix) + latin name of CMI along with suffix ate + Ox. St (in roman number).
R–Mg–X, (CH3–CH2)2Zn, Ziegler natta catalyst, etc.
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m p -bonded organometallic compounds are generally formed by transition elements e.g. Zeise's salt, ferrocene, dibenzene chromium, etc.
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m s - a n d p - b o n d ed o r g a n o m e t a l li c compounds : Metal carbonyls, compounds formed between metal and carbon monoxide belong to this class. Ni(CO)4, Fe(CO)5etc.
eg. : (B)
For cationic comlex like [Cu(NH3)4]SO4
eg. : (C)
Tetraammine copper (II) sulphate.
For neutral complex (like [Fe(CO)5) Name of ligands (with numeral prefix) + Common name of CMI + Ox. St.
p s
Potassium hexacyanoferrate (II)
Name of ligands (with numeral prefix) + Common name of CMI + Ox. St (In roman number) + Name of anion (without numeral prefix)
Synergic bonding
M
For anionic complex (like K4[Fe(CN)6])
(In roman number)
ABMO C
O
eg. : (D)
Pentacarbonyl iron (O)
Rule same just apply alphabetical order when write the name of ligands. e.g. [Pt(NH3)2Cl2] Diamminedichloroplatinum (II)
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d-BLOCK (Transition Elements) DEFINITION Incomplete n and n–1 shell in atomic or in ionic state. Zn, Cd & Hg – are d-block nontransition elements.
ns
0–2
(n–1)d
1–10
1 2nd 3rd 4th st
ì Cr = 4s1 3d 5 0 10 Exceptions í 1 10 , Pd = 5s 4d îCu = 4s 3d
TRANSITION SERIES Sc21 — Zn30 Y39 — Cd48 La57, Hf72 — Hg80 Ac89, Unq 104— Uub112
3d series 4d series 5d series 6d series
9 + 1 = 10 9 + 1 = 10 9 + 1 = 10 9 + 1 = 10
ATOMIC RADIUS
OXIDATION STATE
3d series Sc > Ti > V> Cr >Mn ³ Fe ; CO ; Ni £ Cu < Zn
Transition elements exhibit variable oxidation state due to small energy difference of ns and (n–1)d electrons. r Sc(+3) and Zn(+2) exhibit only one oxidation state r Common oxidation state is +2 r 3d series highest oxidation state is +7 (Mn) r In d-block series highest oxidation state is +8 (Os, Ru) r In carbonyl compound oxidation state of metals is zero due to synergic effects. r Their higher oxidation states are more stable in fluoride and oxides. r Higher oxidation states in oxides are normally more stable than fluorides due to capability of oxygen to form multiple bonds. eg. stable fluoride in higher oxidation state of Mn is MnF4 while oxide is Mn2O7 Some more stable oxidation states of d-block elements
In a group 3d to 4d series increases but 4d and 5d series nearly same due to poor shielding of f electron. (Lanthanide contraction) 3d < 4d ; 5d Smallest radius – Ni e.g.% Ti < Zr ; Hf Largest radius – La
Melting point :s-block metals < d-block metals In a series on increasing number of unpaired e– mpt increases upto Cr then decreases. Sc < Ti < V < Cr > Mn < Fe > Co > Ni > Cu > Zn ¯
¯
Half filled d 5 \ weak metallic bond
Melting point
Fully filled d10 \ weak metallic bond
Zn > Cd > Hg Cu > Ag £ Au
(data based)
E.N. Exception Zn < Cd < Hg Density : s-block metals < d-block metals. 3d series Sc < Ti < V < Cr < Mn < Fe < Co £ Ni < Cu > Zn Density in a Group 3d < 4d Cu > Au > Al E5555555555 F p - block d - block
94
Cu +2
Mn +2
Pt +4
Ag +1
Cr +3
Sc +3
Au +3
Ni +2
Common oxidation states Ti(+4),
V(+5)
Fe(+2, +3), Co(+2,+3)
Cr(+3,+6) Mn(+2,+4,+7) Ni (+2)
Pt (+2+4)
In p-block lower oxidation states of heavier elements are more stable while in d-block heavier element, higher oxidation state are more stable. eg. In VIB gp Mo(+6) & W(+6) are more stable than Cr(+6)
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GENERAL ELECTRONIC CONFIGURATION
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MAGNETIC PROPERTY All transition elements are paramagnetic due to presence of unpaired electrons. They attract when magnetic field is applied. Magnetic moment of unpaired electron is due to spin and orbital angular momentum. "Spin only" magnetic moment can be calculated by using formula m = n(n + 2) Bohr magneton. (n is number of unpaired e–.) If
n is 1 m = 1.73 BM
n is 2 m = 2.84 BM
n is 4 m = 4.90 BM
n is 5 m = 5.92 BM
n is 3 m = 3.87 BM
Substances that are not attracted by applied magnetic field are diamagnetic. They have all the electrons paired. dblock element and ions having d0 and d10 configuration are diamagnetic.
COLOUR Colour in transition metal ions is associated with d–d transition of unpaired electron from t 2g to eg set of energies. This is achieved by absorption of light in the visible spectrum, rest of the light is no longer white. Colourless – Sc3+, Ti4+, Zn2+ etc Coloured – Fe3+ yellow , Fe2+ green, Cu2+ blue, Co3+ blue etc Interstitial compounds : When less reactive nonmetals of small atomic size eg. H, B, N, C, Trapped in the interstitial space of transition metals, interstitial compounds are formed, like :- TiC, Mn4N, Fe3H etc. They are nonstoichiometric compounds.
They have high melting point than metals.
ALLOYS
CATALYST
Solid mixture of metals in a definate ratio
Transition metals & their compounds act as catalyst due to –
(15% difference in metallic radius) They are hard and having high melting point. eg.
They are chemically inert.
Brass (Cu + Zn)
–
Variable oxidation state
–
Tendency to form complex
eg.
Bronze (Cu + Sn) etc. Hg when mix with other metals form semisolid amalgam except Fe,Co,Ni, Li.
V2O5 – Contact process Fe
– Haber process
Ni
– Catalytic hydrogenation
Important reactions of d-block elements
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(a) Cu2+ + 4I– ¾® Cu2I2(s) + I2
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2 (b) CuSO4 + KCN ¾® K2SO4 + Cu(CN) Excess Unstable
(e)
100° C 230° C ¾ ® CuSO4 .H2O ¾¾¾ ¾ ® CuSO 4 CuSO 4 .5H 2 O ¾¾¾ light greenish blue
(CN)2 2Cu(CN)2 ¾® 2CuCN + Cyanogen
720° C ¾¾¾ ¾ ® CuO + SO2 +
CuCN + 3KCN ¾® K3[Cu(CN)4] (c)
H2 O + CO2 ® CuCO3 .Cu(OH)2 Cu ¾¾¾¾¾ moist air
(d)
(f)
green
Aqua regia Au ¾¾¾¾¾¾ ® H[AuCl 4 ] + NOCl + H 2 O (3HCl + HNO3 )
Heating AgNO 3 ¾¾¾¾ ® Ag + NO2 +
1 O2 2
Heating AgCO3 ¾¾¾¾ ® Ag + CO2 +
1 O2 2
Colourless
Hg2Cl2 + NH4OH ¾® Hg
1 O2 2
NH2 Cl Black
(g)
FeSO4 + H2 SO4 NO3- / NO2- ¾¾¾¾¾¾ ® éëFe ( H2 O )5 NO + ùû SO 4
Brown ring complex
(h) AgBr + 2Na2S2O3 ¾® Na3[Ag(S2O3)2] + NaBr Photographic complex
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COMPOUNDS OF D-BLOCK ELEMENT A.
K2Cr2O7 : Method of preparation : 4FeO.Cr2O3 + 8Na2CO3 + 7O2 (Chromite)
8Na2CrO4 + 2Fe2O3 + 8CO2 K2Cr2O7
Important point : •
Cr2 O7-2 CrO4-2 -
•
K 2Cr2O7 used in volumetric analysis not Na2Cr2O7.
•
D ® 2K 2CrO 4 + Cr2O3 + O2 Hetaing effect ® 2K 2Cr2 O7 ¾¾
•
Chromyl chloride test ® Used to detect ionic chloride (Cl–)
H+
Yellow
OH
Orange
3 2
NaCl + K2Cr2O7 + H2SO4 ¾® CrO2Cl2 (Red orange) •
With H2O2 ® Cr2O7–2 + H+ + 4H2O2 ¾® CrO5 (Deep Blue sol.)
•
Act as an oxidising agent.
H2S
S
SO2
SO4–2
–
NO3–
SO3–2
SO4–2
Sn+2
Sn+4
Fe+2
Fe+3
Br–
Br2
NO2
I
–
I2
C2H5OH
CH3COOH (drunken drive test) +3
Cr (green)
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Acidified K2Cr2O7 (Orange)
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KMnO4 : Method of preparation : Cl2 KOH MnO2
K2CO3
K2MnO4
H2O + O3
K2MnO4 (Green)
CO2
KMnO4 KMnO4 KMnO4 (Purple)
Property : •
Effect of heating : 2KMnO4 ¾® K2MnO4 + MnO2 + O2
•
With conc. H2SO4 : conc. ® Mn2 O7 (explosive) KMnO 4 ¾¾¾¾ H2 SO 4
•
acts as oxidising agent in Acidic/Neutral/Alkaline (a)
Acidic
(b)
Neutral/Weak alkaline
KMnO4 H2S
S
SO2
SO4
–
NO3
NO2 Fe
+2
Fe
–
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–2
S2O3
BrO3–
I–
IO3–
–2
SO4
–2
Mn+2
+3
MnO2 MnO4
Cl2
H2CrO4 S2O3
Br–
–
Cl
E
KMnO4
CO2 + H2O
–2
–2
S4O6 +2
Mn
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METALLURGY Branch of process to extract metal from their respective ore Ore : Minerals from which metal can be extracted economically & easily.
METALLURGICAL PROCESS
TYPES OF METALLURGY Pyrometallurgy
Hydrometallurgy
Electro metallurgy
Temp. is involved
Solution is involved
Electric involved
For heavy metals
According to E.C.S.
eg. IA, IIA, Al
eg. Fe, Zn, Cu, Hg, Sn, etc
For metals placed below H
1. Mining : Ore obtain in big lumps (less reactive) 2. Crushing/grinding/pulverization : Big lumps convert into powder (more reactive) 3. Concentration : To remove matrix/ gangue (major impurities) from ore To increase the concenration of ore particle in ore sample.
eg. Cu, Ag, Au
CONCENTRATION (I) Physical process
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(a) Gravity separation /Hydraulic washing/ Levigation
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(b) Magnetic separation
(II) Chemical/leaching
for
(c) Froath floatation
Al Ag, Au Baeyer process (NaOH)
Based on diff. in sp. gravity
Based on diff. in mag. properties
Based on diff. in wetting properties
for oxides/ carbonates ore
Used to separate s & p block compound from transitional elements compounds
Sulphide ores
Ag, Au, are concentrated by cyanide process.
Red(Fe2O3) Al2O32H2O
Hall process (Na2CO3)
White(SiO2) Serpeck process (C & N)
Frother - pine oil Floating agent - sodium ethyl xanthate depressant - NaCN
CALCINATION & ROASTING (I) Calcination
(II) Roasting
In absence of air
In presence of air
for Carbonate /Hydroxide/Oxide ore
for Sulphide ore
CO2 & H2O are to be removed
Impurity of S, P, As, SO2 to be removed
MCO3 ® MO + CO2
MS + O2 ® MO + SO 2
M(OH)2 ® MO + H2 O
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REDUCTION : To obtain metal (95 to 98%) from metal oxide.
Extraction of Al(Hall-Herault Process) ! Al can be extracted from Al 2O3 ! To decrease fusion temp. of Al2O3, Na3 AlF6 & CaF2 is to added ! Na3 AlF6 & CaF2 (Neutral flux) increase the conductivity & reduce the fusion temp.
Extraction of Na (Down cell process) ! Na can be extracted from NaCl ! Neutral flux (CaCl2) to be added to decrease the fusion temp of NaCl ! Neutral flux - substance used to increase the conductivity of NaCl ! Decrease the fusion temp. of ionic compounds of (IA, IIA, Al) which is more than the melting point of metal.
l
l l l l
100
The graphical representationof Gibbs energy was first used by H.I.T. Ellingham. This provide a sound basis for considering the choice of reducing agent in the reduction of oxides. This is known as Ellingham diagram such diagram help us in predicting the feasibility of thermal reduction of an ore. The criteria of feasibility is that at a given temperature, Gibbs energy of reaction must be negative. At high temperature 'C' is the best reducing agent. At low temperature 'CO' is the best reducing agent. In blast furnace reduction takes place at low temperature
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REFINING : To obtain metal (99.98%)
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HYDROGEN Method of preparation : (A) Metal placed about H on reaction with acid. Base or H2O can produce H2. Base + Amp. metal ¾¾® Soluble complex + H2 (Be,Al,Zn,Sn,Pb)
Acid + Metal ¾¾® M.Salt + H2 ( dil )
(B)
Water + Highly reactive metal ¾® M. hydroxide + H2 Important point : • Only Mn, Mg gives H2 on reaction with very dil HNO3. From hydrocarbon : 1270K ® nCO + (3n + 1)H2 Cn H2n +2 + nH2O ¾¾¾¾ Ni
CH 4 + H2 O ¾¾® CO + 3H2 E555555F syn.gas
Ionic hydride – s-block element (except, Be & Mg) (forms polymer having 2e-3c bond) Interstitial hydride – d & f-block element Hydride
– Non stoichiometric compound – Metallic hydride Covalent hydride – p-block element
Electron deficient th (Group 13 ) BH3 Electron precise th (Group 14 ) CH4
Heavy Water (D2O) – Dur to repeated electrolysis of H2O. – Chemical reaction some as H2O but rate of reaction are slow. – N2O5 + H2O ¾® 2HNO3 (Nitric acid) N2O5 + D2O ¾® 2DNO3 (Deutero nitric acid) – Used as a neutron moderation and used in nuclear reactor. H2O2 - Hydrogen peroxide. Method of preparation (a) BaO2.8H2O(s) + H2SO4 ¾® BaSO4 + H2O2(aq) + H2O(l) (b) Electrolytic process - 50% H2SO4 At cathode 2H+ + 2e– ¾® H2 At anode 2HSO4– ¾® H2S2O8 H2S2O8 + 2H2O ¾® 2H2SO4 + H2O2
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Electron rich hydride th th th 15 , 16 , 17 group
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Property : Can acts as oxidising as well as reducing agent. R.A. H2O2
O2
O.A.
H2O
disproportionali
H2O + 1 O2 2
• Non-planar. Half open book like structure. Uses - Bleaching agent, Antiseptic (H2O2 + N2H4) as Rocket propellent, 30% solution of H2O2 is known as perhydrol. Hardness - Due to HCO3 , Cl & SO4 of Ca & Mg –
Temporary hardness – +2 +2 (HCO3 of Ca & Mg )
–
–2
+2
+2
by boiling Ca(HCO3)2 Mg(HCO3)2
D D
CaCO3 + H2O + CO2 Mg(OH)2 + 2CO2
Clarke process - addition of slaked lime Ca(HCO3)2 + Ca(OH)2 2CaCO3 + 2H2O
Hardness
Permanent hardness – –2 +2 +2 (Cl , SO4 of Ca & Mg )
Washing soda (Na2CO3) CaCl2 + Na2CO3 CaCO3¯ + 2NaCl Calgon - Sodium hexametaphosphate Na2[Na4(PO3)6] Permutit - Hydrated sodium alumino silicat
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Na2Al2Si2O8.xH2O (Sodium Zeolite)
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Ion exchange resin
Cation exchange – RCOO H|+
Anion exchange resis + – R–NH3 OH
103
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ORGANIC CHEMISTRY
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Carboxylic acid The order of priority of functional groups used in IUPAC nomenclature of organic compounds.
TABLE FOR IUPAC NOMENCLATURE
Sulphonic acid
O –C–OH –SO3H
Anhydride
Ester Acid halide Acid amide Carbonitrile/Cyanide Aldehyde Ketone
O –C–OR O –C–X O –C–NH2 –CºN O –C–H O –C–
Prefix
Carboxy
Suffix
- oic acid *Carboxylic acid
Sulpho
sulphonic acid
×
oic-anhydride
Alkoxy carbonyl or Carbalkoxy
alkyl....oate
Haloformyl or Halocarbonyl Carbamoyl/ Amido Cyano Formyl or Oxo
*Carboxylate
- oyl halide *Carbonyl halide
- amide *Carboxamide
nitrile
*Carbonitrile
- al
*Carbaldehyde
Keto or oxo
- one
Alcohol
–OH
Hydroxy
- ol
Thio alcohol
–SH
Mercapto
thiol
Amine
–NH 2
Amino
amine
Ether
–O–R
Alkoxy
–
Epoxy
–
Nitro
–
Nitro derivative
–C – C– O –NO 2
Nitroso derivative
–NO
Nitroso
–
Halide
–X
Halo
–
Oxirane
Double bond
C=C
–
ene
Triple bond
CºC
–
yne
* Special suffix
106
Structure
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Functional group
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ISOMERISM DEFINITION Compounds having same molecular formula but differ in atleast one physical or chemical or biological properties are called isomers and this phenomena is known as isomerism.
Types of Isomerism : (A) Structural isomerism
(B) Stereo isomerism
(A) STRUCTURAL ISOMERISM Structural isomerism is a form of isomerism in which molecules with the same molecular formula have atoms bonded together in different orders. TYPES OF STRUCTURAL ISOMERISM CHAIN ISOMERISM This type of isomerism is due to difference in the arrangement of carbon atoms constituting the chain. Key points : Parent carbon chain or side chain should be different. e.g. C5H12 : CH3 – CH2 – CH2 – CH2 – CH3
n-propyl methylether
CH3 – CH2 – O – CH2 – CH3
n-pentane
diethyl ether
CH3
RING-CHAIN ISOMERISM In this type of isomerism, one isomer is open chain but another is cyclic.
CH3
CH3
iso-pentane
neo-pentane
POSITIONAL ISOMERISM It occurs when functional groups or multiple bonds or substituents are in different positions on the same carbon chain. Key point : Parent carbon chain remain same and substituent, multiple bond and functional group changes its position. CH3
CH3
e.g. C6H4(CH3)2 :
, o-xylene
CH3
m-xylene
CH3
,
CH3
p-xylene
FUNCTIONAL ISOMERISM It occurs when compounds have the same molecular formula but different functional groups. e.g. C3H9N : CH3– CH2 – CH2 – NH2, 1-propanamine
CH3 – CH2 – NH – CH3, N-methylethanamine
CH3
CH3 – N – CH3, N, N-dimethylmethanamine
108
e.g. C3H6 : CH3 – CH = CH2 propene
CH2 H2C–CH2 cyclopropane
• For chain, positional and metamerism, functional group must be same. • Metamerism may also show chain and position isomerism but priority is given to metamerism. TAUTOMERISM This type of isomerism is due to spontaneous interconversion of two isomeric forms into each other with different functional groups in dynamic equilibrium. Conditions : O O (i) Presence of – C – or – N ® O (ii) Presence of at least one a-H atom which is attached to a saturated C-atom. e.g. Acetoacetic ester. O OH
CH3–C–CH2COOC2H5
CH3–C=CHCOOC2H5
keto form
enol form
ENOL CONTENT ENHANCE BY: * Acidity of a-H of keto form * Intra molecular H-Bonding in enol form * Resonance in enol form * Aromatisation in enol form
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H3C – CH – CH2 – CH3 , H3C – C – CH 3
CH 3
METAMERISM This type of isomerism occurs when the isomers differ with respect to the nature of alkyl groups around the same polyvalent functional group. e.g. C4H10O : CH3 – O – CH2 – CH2 – CH3
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(B)STEREOISOMERISM Compounds with the same molecular formula and structural formula but having difference in the spatial arrangement of atoms or groups in 3D space are called stereoisomers and the phenomenon is called stereoisomerism. TYPES OF STEREOISOMERISM GEOMETRICAL ISOMERISM
OPTICAL ISOMERISM
It is due to restricted rotation and is observed in following systems
Compounds having same molecular and structural formula but different behaviour towards plane polarised light are called optical isomers and this phenomenon is called optical isomersim.
a
a C=C
b
a
b , b
C=N–OH
, a
e.g.
H HOOC
C CH3
C=C
H
H
COOH
HOOC
cis maleic acid
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b b
b
C=C
l
The carbon atom linked to four different groups is called chiral carbon.
l
Fischer projection : An optical isomer can be represented by Fischer projection which is planar representation of three dimensional structure. Fischer projection representation of lactic acid
COOH
(2-hydroxypropanoic acid)
H 3
trans > cis
(ii) Dipole moment
cis > trans
(iii) Boiling point
cis > trans
(iv) Melting point
trans > cis
Calculation of number of geometrical isomers : Unsymmetrical
2n
Symmetrical
2n–1 + 2 m–1 n 2
2
COOH
1
C H 3 – C H – C O O H : HO
General physical properties of geometrical isomer of but-2-ene (i) Stability
Optically inactive • meso
Condition :
l
trans fumaric acid
m=
Types of optical isomers (1)Optically active (2) • dextrorotatory (d) • laevorotatory (l)
l
Molecule should be asymmetric or chiral i.e. symmetry element (POS & COS) should be absent.
Cis-trans isomerism : The cis compound is the one with the same groups on the same side of the bond, and the trans has the same groups on the opposite sides. Both isomers have different physical and chemical properties.
l
E
a a
b,
a
(Ring greater than 7 member with , double bond)
l
N=N
n +1 m= (If n is odd) 2
OH
H
OH CH3
l
Configuration of optical isomer : (a) Absolute configuration (R/S system) (b) Relative configuration (D/L system)
l
Determination of R/S configuration : Rule-1
Assign the priority to the four groups attached to the chiral carbon according to priority rule.
Rule-2
If lowest priority 4 is bonded to vertical line then moving
Rule-3
2
3
Clockwise
R
Anti clockwise
S
If lowest priority 4 is bonded to horizontal line then moving
1 * Where n = number of sites where GI is possible.
H CH3
1 (If n is even)
COOH
2
3
Clockwise
S
Anti clockwise
R
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DETERMINATION OF D/L SYSTEM : • Reference molecule glyceraldehyde • It is used to assign configuration in carbohydrate, amino acid and similar compounds Rule: Arrange parent carbon chain on the vertical line • Placed most oxidised carbon on the top or nearest to top. • On highest IUPAC numbered chiral carbon If OH group on RHS ® D If OH group on LHS ® L H HO H H
CHO OH H OH OH C H 2 –O H
CH O H OH H H CH 2– O H
HO H HO HO
l
l
l
l
l
D – G lucose L– G lu co se CIP SEQUENCE RULE : The following rules are followed for deciding the precedence order of the atoms or groups :(i) Highest priority is assigned to the atoms of higher atomic number attached to asymmetric carbon atom. (ii) In case of isotopes, isotopes having higher atomic mass is given priority. (iii) If the first atom of a group attached to asymmetric carbon atom is same then we consider the atomic number of 2nd atom or subsequent atoms in group. (iv) If there is a double bond or triple bond, both atoms are considered to be duplicated or triplicated.
l
Non-superimposable mirror images are called enantiomers which rotate the plane polarised light up to same extent but in opposite direction. Diastereomers are stereoisomers which are not complete mirror images of each other. They have different physical and chemical properties. Meso compounds are those compounds whose molecules are superimposable on their mirror images inspite of the presence of asymmetric carbon atom. An equimolar mixture of the enantiomers (d & l) is called racemic mixture. The process of converting d- or l- form of an optically active compound into racemic form is called racemisation. The process by which dl mixture is separated into d and l forms with the help of chiral reagents or chiral catalyst is known as resolution. Compound containing chiral carbon may or may not be optically active but show optical isomerism. For optical isomer chiral carbon is not the necessery condition. Calculation of number of optical isomers
l
l
The compound
Optically active forms
Unsymmetrical
2
Symmetrical If n = even
2(n–1)
2 2 –1
Symmetrical If n = odd
2(n–1) – 2(n–1)/2
2(n–1)/2
n
Zero n
* Where n = no. of chiral carbon
CONFORMATIONAL ISOMERISM
Ha Ha
Hc Hc
Ha Hb
Hb Hb
Eclipsed form (lea st stable)
110
Hc
60°
Hc
Hb Ha
Staggered form (m ost stable)
4
l
CH3 CH3
H H
H
CH3
1
H
60° Rotation
H Gauche
CH3 H
CH3
60° Rotation
H H
Fully eclipsed (less stable)
l
3
Conformations of butane : CH3 – CH2 – CH2 – CH3
H
H H
H
CH3
H
60° Rotation
CH3 H
Partially Eclipsed form
H
CH3
H
Anti Staggered-form (most stable)
The order of stability of conformations of n-butane. Anti staggered>Gauche>Partially eclipsed>Fully eclipsed.
l
Relative stability of various conformation of cyclohexane is Chair > twist boat > boat > half chair (Chiral)
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The different arrangement of atoms in space that results from the carbon-carbon single bond free rotation by 0-360° are called conformations or conformational isomers or rotational isomers and this phenomenon is called conformational isomerism. Newmann projection : Here two carbon atoms forming the s bond are represented one by circle and other by centre of the circle. Circle represents rear side C and its centre represents front side carbon. The C–H bonds of front carbon are depicted from the centre of the circle while C–H bond of the back carbon are drawn from the circumference of the circle.
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CH APTER
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REACTION MECHANISM Electrophiles are electron deficient species.
Relative electron withdrawing order (–I order)
eg. H , R , NO , X , PCl 3, PCl5
- N F3 > - N R 3 > - N H 3 > –NO2 > –CN > –COOH
Å
Å 2
Å
Å
Å
Å
Nucleophiles are electron rich species.
> –X > –OR > –OH > –CºCH > –NH2 > –C6H5 > –CH = CH2 Relative electron releasing order (+I order)
e.g. C l, C H 3, O H , R O , C N , N H 3, R O H , C H 2 =CH 2 , C H ºC H
– N H > –O > – C O O >3°alkyl>2°alkyl>1° alkyl>–CH3
RELATIVE STABILITY ORDER (A) Stability of carbocation
ACIDIC STRENGTH µ Stability of conjugate base
Å
( N H4 and H3 OÅ are not electrophile)
Å
Å
Å
> (Ph)3 C > (Ph)2 CH > Ph - CH2 > CH2 = CH - CH2 > Å
Å
Å
Å
Å
Å
(CH3 )3 C > (CH3 )2 C H > CH3 C H2 > C H3 > CH2 = C H > CH º C
(B) Stability of free radical & > (Ph) CH & > PhCH & & (Ph)3 C 2 2 > CH2 = CH - CH2 >
& > (CH ) CH & > CH CH & & (CH3 )3 C 3 2 3 2 > CH3 (C) Stability of Carbanion Q
Q
µ Ka µ
Å
Q
(i) H2O > CH º CH > NH3 (ii) CH º CH > CH2 = CH2 > CH3–CH3 OH
(iii) R–SO3H > R–COOH >
Q
Q
Q
(v)
OH NO2
NO2
(vi) CCl3COOH > CHCl2COOH > CH2ClCOOH (vii) CH –CH –CH–COOH > CH –CH–CH COOH > CH–CH CH COOH 3
•
• •
Basic strength of amine :In aqueous medium R Þ –CH3 2° > 1° > 3° > NH3 R Þ –CH2CH3 2° > 3° > 1° > NH3 In gaseous medium R Þ –CH3 3° > 2° > 1° > NH3 R Þ –CH2CH3 3° > 2° > 1° > NH3 Reactivity towards nucleophile (NAR) (1) HCHO > CH3CHO > (CH3)2CO (2) CCl3CHO > CHCl2CHO > CH2ClCHO Reactivity order towards acyl nucleophilic substitution reaction Acid chloride > anhydride > ester > amide Order of electronic effect Mesomeric > Hyperconjugation >Inductive effect Stability of alkene µ no. of a-hydrogen
(ix) C6H4
112
Heat of hydrogenation µ
2
2
F
2
2
F
Phenol > m > p > o
OH p > o > m > Phenol
NO2 OH
NO2
OH
NO2
(x)
> NO2
OH
NO2
>
OH NO2
>
NO2
COOH (xi) C6H4
NO2
o > p > m > benzoic acid
COOH (xii) C6H4
CH3
o > benzoic acid > m > p
cis form
RCH=CH2 > CH2=CH2 •
3
OH C H (viii) 6 4 CH3
R2 C=CR 2 > R2 C=CHR > R2 C=CH2 >RCH=CHR > RCH=CHR trans form
2
F
1 BASIC STRENGTH µ Kb µ pK b
•
> H CO O H > C 6 H 5 C O O H > C H 3C O O H
NO2
Q
CH3 > CH3 CH2 > (CH3 )2 CH > (CH3 )3 C
•
> R–OH
(iv) HCOOH > CH3COOH > CH3CH2COOH
(Ph)3 C > (Ph)2 CH > Ph - C H2 > CH2 = CH - CH2 > Q
1 pK a
1 Stability of alkene
(xiii) C6H 4
COOH Cl
o > m > p > benzoic acid
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PRACTICAL ORGANIC CHEMISTRY LASSAIGNE'S METHOD (detection of elements)
PURIFICATION METHODS DISTILLATION TECHNIQUES
Type :
(A) SIMPLE DISTILLATION Conditions (i) When liquid sample has non volatile impurities (ii) When boiling point difference is 80 K or more. Examples (i) Mixture of chloroform (BP = 334K) and Aniline (BP = 457K) (ii) Mixture of Ether (b.p. = 308K) & Toluene (b.p. = 384K) (iii) Hexane (342K) and Toulene(384K)
(B) FRACTIONAL DISTILLATION When b.p. difference is 10K Examples (i) Crude oil in petroleum industry (ii) Acetone (329 K) and Methyl alcohol (338K)
(C) DISTILLATION UNDER REDUCED PRESSURE (Vacuum distillation) When liquid boils at higher temperature and it may decompose before b.p. is attained. Example (i) Concentration of sugar juice (ii) Recovery of glycerol from spent lye. (iii) Glycerol (D) STEAM DISTILLATION P = P1 + P2 When the substance is Vapour Vapour Vapour immiscible with water and pressure pressure pressure steam volatile. of of water Example : Organic (i) Aniline is separated liquid from water (ii) Turpentine oil (iii) Nitro Benzene (iv) Bromo Benzene (v) Naphthalene (vi) o-Nitrophenol
Sodium extract Na + C + N D
Element Nitrogen
Confirmed test (NaCN+FeSO4+NaOH) boil and cool +FeCl 3+conc.
NaCN
HCl ® Fe4[Fe(CN) 6]3 Prussian blue colour
(i) Na2S + Na2[Fe(CN)5NO]
2Na + S D
Sulphur
sodium nitrosopruside
® Na4[Fe(CN)5NOS] a deep violet colour
Na2S
PbS¯ Black ppt. NaX + HNO3 + AgNO3
Na + X D
Halogen
(i) White ppt. soluble in aq. NH3 confirms Cl. (ii) Yellow ppt. partially soluble in aq. NH3 confirms Br.
NaX
(iii) Yellow ppt. insoluble in aq. NH3 confirms I. Nitrogen and sulphur together
As in test for nitrogen; instead of green or blue colour, blood red colouration confirms presence of N and S both
Na+C+N+S D NaCNS Sodium thiocyanate (Blood red colour)
Estimation of carbon and hydrogen - Leebig's method CxHy +
x+y y O2 ®xCO2 + H2O 4 2 12
wt. of CO
2 % of C = 44 ´ wt. of org. compd ´ 100
% of H =
2 wt. of H2O ´ ´ 100 18 wt. of org compd
Note : This method is suitable for estimation if organic compound contains C and H only. In case if other elements e.g., N, S, halogens are also present the organic compound will also give their oxides which is being absorbed in KOH and will increase the percentage of carbon and therefore following modification should be made.
114
ESTIMATION OF NITROGEN Kjeldahl's method : Duma's method : In this method nitrogen containing The nitrogen containing organic compound yields nitrogen gas on compound is heated with conc. H2SO4 in heating it with copper (II) oxide in presence of copper sulphate to convert the presence of CO 2 gas. The nitrogen into ammonium sulphate which is mixture of gases is collected over decomposed with excess of alkali to liberate potassium hydroxide solution in ammonia. The ammonia evolved is which CO2 is absorbed and volume of nitrogen gas is determined. æ Vol. of N2 ö ç collected ÷ ç at N.T.P. ÷ % of N = 28 ´ ç ÷ ´ 100 22400 ç Wt. of ÷ organic ç ÷ è compound ø Note : This method can be used to estimate nitrogen in all types of organic compounds
1.4 ×volume (ml) of H 2 SO 4 used for % of N =
Neutralisation ×normality of acid wt of organic compound
Note : This method is simpler and more convenient and is mainly used for finding out the percentage of nitrogen in food stuffs, soil, fertilizers and various agricultural products. This method cannot be used for compound having nitro groups, azo group (–N = N–) and nitrogen in the ring (pyridine, quinole etc.) Since nitrogen in thes e compounds is not quantitatively converted in to ammonium sulphate.
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QUANTITATIVE ANALYSIS OF ORGANIC COMPOUNDS
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DISTINCTION BETWEEN PAIRS OF COMPOUNDS UNSATURATION TEST
DISTINCTION BETWEEN 1°, 2° & 3° ALCOHOLS
(a) Double/Triple bonded Compounds (C = C)/(C º C)+ Br2 in CCl4 (Brown colour) ® Colourless compound
R •
•
Br R – CH – CH – R
R – CH = CH – R + Br2
R – C º C – R + Br2 (Alkyne) (Brown)
•
R – CH – CH – R + MnO2 Brown ppt OH OH
(Cold, dilute)
(Colourless)
• R – C º C – R' + KMnO4 (Alkyne)
(Hot, dilute)
Brown ppt.
MnO2 + RCOOH + CO2 + H2O
R – CH2 – Cl Cloudiness appears after 30 minute
OH
•
H3C – CH – R type of alcohols give iodoform test.
OH
•
H3C – CH – R + I2
NaOH Iodoform test
CHI 3 + RCOONa Iodoform (Yellow ppt.)
OH + FeCl3
•
R – C º CH Terminal alkyne Cu 2Cl2 + NH 4OH
Red ppt.
NATURE OF X-GROUP IN C–X BOND R – OH + KX
3H+ + [Fe(OC6H5)6]3– + 3HCl
Carbonyl + 2, 4-DNP (Bredy's reagent) compound
HNO3 AgNO3
AgX
Precipitate
If X is Cl, precipitate will be white and for Br yellow precipitate will be obtained.
Yellow/orange crystal O2N
NO2 H C = O + N – NH H
NO2
C = N – NH
NO2
(Bredy's reagent)
AgNO 3 + NH 4OH
White ppt.
NH4Cl + H2O + R – C º C – Cu
(neutral )
Violet colouration
Red ppt.
NH4NO3 + H2O + R – C º C – Ag
Phenol + ferric chloride ¾¾® Violet colouration
CARBONYL GROUP
Ammonical cuprous chloride
White ppt.
PHENOL
6
Terminal alkyne Ammonical silver nitrate
116
Lucas reagent Heat
Brown ppt. (Colourless)
TEST FOR TERMINAL ALKYNE
R – CH – Cl Cloudiness appears within five minutes
Lucas reagent is anhydrous ZnCl2 + conc. HCl. HALOFORM REACTION IN ALCOHOL
Baeyer's reagent is cold, dilute KMnO4 solution having pink colour. Note : The above test are not given by Benzene. Although it has unsaturation.
R – X + aqueous KOH
R – CH2 – OH
MnO2 + RCOOH + R'COOH
(Hot, dilute)
• R – C º C – H + KMnO4
R – CH – OH
Primary alcohol
(b) Double/Triple bonded Compounds + Baeyer's reagent (Pink colour) ¾® Brown precipitate
(Alkene)
R Lucas reagent Room temperature
Secondary alcohol
(Colourless)
• R – CH = CH – R + KMnO4
Cloudiness appears immediately
R •
Br Br R–C–C–R Br Br
CCl4
R
Tertiary alcohol
(Colourless)
(Brown)
(Alkene)
R – C – Cl
• All aldehydes and only aliphatic methyl ketones + NaHSO3 ® White crystalline bisulphite (Water soluble). OH R – + R – C – SO 3Na C=O + NaHSO3 H H Aldehyde R H3C
OH C=O + NaHSO3
Methyl ketone
R – C – SO–3Na+ CH3
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•
R – C – OH R
Br
CCl4
R Lucas reagent Room temperature
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Chemistry HandBook
ALLEN ALDEHYDE GROUP
Chloroethane and chlorobenzene
Aldehyde + Tollen's reagent ¾¾® Silver mirror
•
• C2H5–Cl + aq. KOH
Boil
HNO3 AgNO3
C2H5—OH+KCl
AgCl
White ppt.
O R–C–H + 3OHQ + 2[Ag(NH3)2]+
Q
RCOO + 2H2O + 4NH3 + 2Ag
(silver mirror)
•
Aldehyde + Fehling's solution ® Reddish brown precipitate O R–C–H + 2Cu2+ + 5OH—
RCOOQ + 3H2O + Cu2O
•
Cl + aq. KOH
•
• •
H3C – C – group also give iodoform test
Cl + aq. KOH
Boil
H3C–C–R + I2 + NaOH
CHI3 + RCOONa Iodoform (Yellow ppt.)
• •
AROMATIC ALDEHYDE GROUP Aromatic aldehyde + Tollen's reagent ® Silver mirror Aromatic aldehyde + Fehling's soln ® Negative test
Negative test Ag + Silver mirror
Fehling's solution
• •
•
C2H5–Cl + aq. KOH
Boil
(Chloroethane)
C2H5–Br + aq. KOH
Boil
(Bromoethane)
AgBr
Yellow ppt.
OH CH2 + KCl
Boil
CH2 + aq. KOH
HNO3 AgNO3
AgCl
Boil
Cl + aq. KOH HNO , AgNO No reaction 3
3
Chlorobenzene
H2O + CO32— + Cu2O 2Ag + CO32— + H2O
Ethyl chloride and vinyl chloride •
C2H5 – Cl + aq.KOH
Boil
(Ethyl chloride)
Carbylamine reaction
Isonitrile Primary + KOH + CHCl3 (Offensive smell) amine Amines (1°, 2° & 3°) (Hinsberg's test) • Primary amine + Benzenesulphonyl chloride KOH ® Precipitate ¾¾¾ ® soluble
C2H5 – OH + KCl AgCl
(White ppt.)
AMINES (1°)
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AgCl
White ppt.
HNO3 AgNO3
C2H5–OH+KBr
White ppt.
Silver mirror
E
HNO3 AgNO3
C2H5–OH+KCl
(Benzyl chloride)
CHO
Red ppt.
Tollen's reagent
No reaction
Cl
•
Fehling's solution
HCOOH
Boil AgNO3 , HNO 3
AgCl
White ppt.
Benzyl chloride and chlorobenzene
FORMIC ACID
Formic acid
Cl + aq. KOH
Tollen's reagent
COO—
HNO3 AgNO3
OH + KCl
Chloroethane and bromoethane
O Iodoform test
No reaction
Chlorocyclohexane and chlorobenzene
(Reddish brown ppt)
O
Boil AgNO3 , HNO 3
•
H2C=CH–Cl + aq.KOH
HNO3 AgNO3
Boil HNO 3, AgNO 3
No reaction
Vinyl chloride
n-Propyl alcohol and iso-propyl alcohol •
ZnCl2 CH3 CH 2CH2OH + HCl ¾¾¾® CH 3CH2CH2 Cl
No cloudiness at room temp.
•
Secondary amine + Benzenesulphonyl chloride KOH ¾® Precipitate ¾¾¾ ® insoluble
•
Tertiary amine + Benzenesulphonyl chloride ® No reaction
Note : Benzenesulphonyl chloride is called Hinsberg's reagent.
•
OH H3C–CH–CH3
ZnCl2 HCl
Cl H3C–CH–CH3 Cloudiness within 5 minutes
Ethyl alcohol and methyl alcohol (Iodoform test) •
CH3CH2OH + 4I2 + 6NaOH ¾® CHI3 + HCOONa
•
CH3OH + 4I2 + 6NaOH ¾¾® No yellow ppt.
Yellow ppt.
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Ethyl alcohol and acetone (By 2, 4 – DNP)
H3C H3C
O2N C=O+
H N – NH H
Acetone
•
H3C H3C
•
O
NO2
H3C – CH2 – CH + 3OH—+ 2[Ag(NH3)2]+
2, 4-Dinitrophenylhydrazine
O2N
— CH3CH2COO + 2H2O + 4NH3 + 2Ag¯
(Silver mirror)
NO2
C = N – NH
•
(yellow orange crystals)
2,4 - DNP ® No reaction C2H5OH ¾¾¾¾¾
•
Propanal and propanone (Tollen's and Fehling reagent) Propanal + Tollen's reagent ¾¾® Silver mirror
Propanal + Fehling's solution ® Reddish brown precipitate O
Phenol and ethyl alcohol (Neutral FeCl3) • Phenol + Neutral ferric chloride ® Violet colouration
H3C – CH2 – CH + 2Cu2++ 5OH— CH3CH2COO— + 3H2O + Cu2O
(Reddish brown ppt.)
6
OH + FeCl3
3H + [Fe(OC6H5)6] + 3HCl +
3–
Violet colouration
•
Propanone
• CH3CH2OH + Neutral ferric chloride ® No violet color Benzoic acid and phenol (NaHCO 3) • Benzoic acid + Sodium bicarbonate ® effervescence C6H5COOH +NaHCO3 ® C6H5COONa + CO2+H2O •
Fehling's solution
Negative test
Tollen's reagent
Negative test
Pentan-2-one and pentan-3-one (Iodoform test) O
• H3C – CH2 – CH2 – C – CH3 + I2 + NaOH Iodoform test (Pentan-2-one)
Phenol + Sodium bicarbonate ® No effervescence
CHI3 + CH3CH2CH2COONa
(Phenol is less acidic than benzoic acid)
Iodoform (Yellow ppt.)
Propanone and propanol (2, 4 - DNP) O
H3C
C=O+
H N – NH H
NO2 2, 4-DNP
• H3C H3C
Propanal and benzaldehyde (Fehling solution) • Propanal + Fehling's solution ® Reddish brown ppt
O2N
O 2+
–
H3C – CH2 – C – H + 2Cu + 5OH
NO2
C = N – NH
—
CH3CH2COO + 3H2O + Cu2O
Fehling's solution
•
Yellow orange crystals
Benzaldehyde + Fehling's solution ® No precipitate 2+
•
Ethanal and propanal (Iodoform test)
Ethanal
CHI3 + HCOONa Iodoform (Yellow ppt.)
•
HCOOH Methanoic acid
O
• H3C – CH2 – C – H + I2 + NaOH Propanal
118
Iodoform test
No reaction
Methanoic acid and ethanoic acid (Tollen's & Fehling solution)
O Iodoform test
—
CHO + 2Cu + 5OH
Propanol + 2,4-Dinitrophenylhydrazine ® No crystals
• H3C – C – H + I 2 + NaOH
No yellow ppt.
Pentan-3-one
No yellow ppt.
• Ethanoic acid
Fehling's solution
H2O + CO3
Tollen's reagent
2Ag¯+ CO3
2—
2—
+ Cu 2O + H 2O
Fehling's solution
No reddish brown ppt.
Tollen's reagent
No silver mirror
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H3C
•H3C – CH2 – C – CH2 – CH3 + I2 + NaOH Iodoform test
O2N
E
CHAPTER
Chemistry HandBook
ALLEN Ethanal and methanal (Iodoform test) •
CH 3CHO + I2 + NaOH
Iodoform test
Ethanal
•
Aniline and N-methylaniline (Isocyanide test)
CHI 3 + HCOONa Iodoform (Yellow ppt.)
HCHO + I2 + NaOH
Iodoform test
•
•
O
NH – CH3 + CHCl3 + 3KOH (alc.)
N-Methylaniline
Iodoform test
NH2
•
CHI3 +
COONa
(Yellow ppt.)
Aniline
N=N
+ I2 + NaOH
C
Iodoform test
No ppt.
OH
Mild Basic Medium
•
effervescence
Ethyl benzoate + Sodium bicarbonate ® No effervescence
Benzaldehyde and acetophenone (Tollen's test) • Benzaldehyde + Tollen's reagent ® Silver mirror
NaNO2 + HCl
CH2 – OH
(Tollen's reagent)
COO + 2H2O + 4NH3 + 2Ag¯ —
Acetophenone + Tollen's reagent ® No silver mirror
Methyl amine and dimethyl amine (Isocyanide test) • CH3NH2 + CHCl 3 + 3KOH (alc.)
Glucose and fructose •
Glucose+ Br2 + H 2 O ® Gluconic acid + 2HBr
•
Fructose+ Br2 + H 2 O ® No change in color
( brown )
( colorless )
( brown )
CH3NC + 3KCl + 3H2O
•
Glucose + Tollen's reagent ¾¾® Silver mirror
•
Sucrose + Tollen's reagent ¾¾® No silver mirror
Glucose and starch •
Glucose + Fehling's solution ¾¾® Red ppt.
•
Starch + Fehling's solution ¾¾® No red ppt.
Methyl isocyanide (Offensive smell)
OR
CH3
• H3C–NH + CHCl3 + 3KOH(alc.)
OH
No orange dye
Glucose and sucrose
CHO + 3OH— + 2[Ag(NH3)2]+
Methyl amine
CH2 – NH2 Benzylamine
Benzoic acid and ethylbenzoate •C6H5COOH + NaHCO3 ® C6H5COONa + CO2+ H2O
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OH
N2Cl
Diazotisation 0–5°C
Orange dye
(Benzophenone)
E
+ –
NaNO 2 + HCl
O
•
No offensive smell
Aniline and Benzylamine (Diazotisation + phenol)
C – CH3 + I2 + NaOH (Acetophenone)
•
P heny l isoc ya nide (O ffe nsiv e sm ell)
No yellow ppt.
Acetophenone and benzophenone (Iodoform test)
•
N C +3 KC l+3H 2 O
(alc.)
A niline
Methanal
•
N H 2+C H C l 3+3KO H
No offensive smell
Di-methyl amine
•
Glucose + I2 solution ¾¾® No blue colour
•
Starch + I2 solution ¾¾® Blue colour
Aniline and ethyl amine (Diazotisation) NH2
• Aniline
NaNO2 + HCl Diazotisation 0–5°C
N=N
OH
+ –
N2Cl
Mild basic medium
OH
Orange dye p-hydroxy azobenzene
• CH3CH2NH2
NaNO 2 + HCl
OH CH3CH2OH
No Orange dye
Ethyl amine
119
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Chemistry HandBook
120 ALLEN
IMPORTANT NOTES
E
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ALLEN
E Chemistry HandBook
IMPORTANT NOTES
121
Chemistry HandBook
CH APTER
ALLEN
HYDROCARBON
• • •
Reactivity of alkane towards free radical halogenation is µ stability of free radical C6H5–CH3>CH2=CH–CH3 >(CH3)3CH > CH3–CH2–CH3>CH3–CH3>CH4 Reactivity of halogen towards free radical substitution F2 > Cl2 > Br2 > I2 Knocking tendency of petroleum as fuel decrease with increase in side chain. Straight chain > Branched chain Knocking tendency is in the order Olefin > cycloalkane > aromatic
122
•
Boiling point decrease with increase in number of side chain. CH3–CH2–CH2–CH2–CH3 > normal
CH3 > C H 3 – CH – C H 2 – C H 3 > C H 3 – C – C H 3 CH3 CH3 iso
neo
Z:\NODE02\B0B0-BA\HAND BOOK CHEMISTRY\ENG\3_ORGANIC.P65
ALKANE
E
CHAPTER
Chemistry HandBook
ALLEN
R CH OH
PREPARATION
H 2SO 4/D or
CH3
H2/Pd-CaCO 3
H 3PO 4/D or Al2O 3/D
X R CH2 CH2 X CH2
X R CH X
Na/Liq. NH 3
Alc. KOH -HX
Birch Reduction give trans Alkene
D
H
(Markownikov's rule)
O H H3C CH CH3
Less substituted alkene is major product
Z:\NODE02\B0B0-BA\HAND BOOK CHEMISTRY\ENG\3_ORGANIC.P65
E
O H H3C CH CH2 Br Cl H3C CH CH2 Br I H3 C CH CH2 Br
H3 C
HO OH H3 C CH CH2
or dil. Alk. KMnO4 (Bayer's Reagent)
(EAR)
(S yn addition)
O
½O2 /Ag/D or H3CCO3H
H3C CH
CH2
H2O 2
Epoxidation
(EAR)
O
CH2
H H
Dry NaCl
+ Br
H or OH
(EAR)
Anti addition of Br2
d-
Cl
Cl CH2 CH
(FRSR)
cis ® d,l dibromide trans ®meso dibromide Markownikoff Rule (M.R.)
Br
NBS (FRSR) High temp. / Pressure Catalysts
d-
d+
N O
HBr+R2O 2
(FRAR)
(Anti-Markownikov's rule)
(Markownikov's rule)
H3 C CH2OH
+ H3 C
OH
CO2+H2O
combustion Cl2/500°C
I
(Anti addition)
O O H3C C H+ H C H O H3C C OH+CO2
CH3COOH+CO2
3n 2 O2
Br2
CH2
d+
OH CH2
+
KMnO4 D
H3C CH
H 2O2
O LiAlH 4
(EAR)
Br CCl4
KI
H3C CH
H3C CH 18 OH
H 2O/Zn
B 2H 6/THF
( CH3 CH CH2 )3B H
O
H+ /H 2O18
O
O3
(EAR)
CH CH2 Cl OH
OsO4/NaHSO3
X
NaBH 4
NaOH
CH2 Br
O Cl
(EAR)
Hg(OAc )2
(No rearrangement )
Br H3C CH
d- d+
H
(EAR)
O H H3C CH CH3
H OH H3 C CH CH2
REACTIONS
H+ /H 2O
Intermediate :carbocation (thus rearrangement occurs)
Å
(CH3-CH2)4NOH
Hoffman Rule
Cold Conc. H2SO 4 (EAR)
HBr, HCl, HI
b
H3C–CH2–CH=CH2
Saytzeff Rule
X H3C CH CH3
a
D
Elimination Reaction E1 & E2 H H a H3C–CH–CH–CH2 b b Y
more substituted alkene is major product
H
H O R C O CH2 CH R
Pyrolysis D
Zn dust For Higher Alkene
H3C–CH=CH–CH3
HOO 2SO
R–C º C–R
Zn dust
Kolbe electrolysis
CH 3–CH–CH2
R–C º C–R
Lindlar Catalyst give cis Alkene
(X:Cl, Br,I)®Saytzeff's Rule
X R CH
Partial reduction
ALKENE
Br
HBr
HBr Peroxide
Br
CH2
(Allylic halogenation)
Br CH2 CH CH2 (Allylic halogenation) —CH—CH ( )n 2—
Polymerisation
CH3 CH 3CH2CH2Br
(Anti-Markownikov's rule)
Rate of EAR : R2C=CR2 > R2C=CHR > RCH=CHR > R—CH2=CH2> CH2=CH2
•
Order of reactivity of olefins for hydrogenation CH2=CH2 > R–CH=CH2 (Reverse of stability)
•
Order of reactivity of alkene towards hydration C H 3 – C = C H 2 > CH3–CH = CH2 > CH2 = CH2 CH3
123
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(EAR)
124 oxidation
Elimination
Chemistry HandBook C HAP TE R
ALLEN
ALKYNE
Kolbe's electrolysis
E
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CHAP TER
ALLEN
E Chemistry HandBook
BENZENE
125
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Chemistry HandBook
126 ALLEN
IMPORTANT NOTES
E
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ALLEN
E Chemistry HandBook
IMPORTANT NOTES
127
C HAP TE R
Chemistry HandBook
ALLEN
PREPARATION
HALOALKANE
H3C CH2 CH2 CH3 Corey house synthesis
H3C CH2 NH2 H3C CH2 C C H
NaI Acetone (C2H5)2CuLi NH3 excess + H C CNa
Wurtz reaction
OH Aq KOH Moist Ag2O
Na Et2O
H3C CH2 CH2 CH3
Br
Wurtz-Fittig Reaction
H3C CH2
Na/Et2 O Mg/Et2 O
C2 H5 MgBr
KCN EtOH
Alc. KOH
H2C CH2
Ag-O-N=O
NaBH4/EtOH---->2° & 3° not 1° R—X
CH3–CH 2–ONO
NaNO2
H3C CH2
NaSH Alc.
SH
+
H3C CH2 N C
—
K O N=O
LiAlH4/Et2 O
(1°,2° not 3° R—X)
H3C CH2 C N
AgCN
+
H3C CH2 H
H3C CH2 OH
H3C CH2 O N O O H3C CH2 N O
AlCl3
CH2 CH3
DMF
F.C. Alkylation
C2H5 O C2H5 (R–Br ® 1°)
CH3-CH2ONa+
PHYSICAL PROPERTIES
H3C CH2
RMgX ¾
RCOO
>
>
Br
128
CH3SNa
S CH3
Br
Br
R–R
RCOOCH3
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H3C CH2 I
(Reactivity order) (R–I>R–Br>R–Cl>R–F)
CH3—X CH3–CH2—X R–X
Reaction with metal
REACTIONS
Nucleophilic substitution S N1 : 3>2>1 S N2 : 1>2>3
E
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C HAP TE R
ALLEN
E Chemistry HandBook
TRI-HALO ALKANE
129
CHAPTER
Chemistry HandBook
ALLEN
GRIGNARD REAGENT REACTION GRIGNARD REAGENT as Nucleophile O
O
O R C O H
O H
(1°) R CH2
H3C
O H
C
C
R
RMgX in
OH R C R R
R C Cl excess/ H 3O +
R
R
H 3O +
C
O
RMgX in
H 3O +
–d +d
RMgBr
O H
OH R CH2 CH2
OEt
C
G.R. 1eq.
OMgBr H C R R
O R C R
N
H 3O+
O H
Å
H O R CH CH2 R
O R
C OEt excess
CH
RMgX inH
CH2 3O
+
O R
C
O2
OEt
1eq. RMgX
O C
O H (3° Alc.) R C R R O R C Cl
R O H
H 3O+ O
OEt
O H R C R R
Cl C Cl RMgX in excess /H 3O +
OEt + H 3O + G.R. (excess)
O Cl
C
Cl
Cl
1 eq.
C
N
R C N + Mg
RMgX
O
O
Cl
R C R
C
Cl
2 eq.
Cl
NH 2
R NH2 + Mg
RMgX
GRIGNARD REAGENT as BASE (Active H-containing compound) H
Mg(OH)Br + R-H Mg(OR)Br + R-H Mg(OD)Br + R-D
H
O
H
R
O
H
D
O
D
H
N
R
H
N
R
RMgBr C O
NH 2
R H + Mg
–d +d
R'
H
R H + Mg
R
C
MgBr +R-H Mg(NH2)Br+R-H
H
NH R Br NR2 Br
R H + R' C CMgBr O
O
R H+
MgBr O
130
Br Cl Br Cl
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O R C R
O R C R
Cl
O
O H R C R R
H3O +
C
1eq. RMgX
H3O+
O H C R OH R CH R
R
O
O H (2°) R CH CH 3
(3°)
O H
C
H 3O +
OH
OH R C R R
R C OEt RMgX in excess/H O+ 3
C O H 3O +
E
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ALLEN
E Chemistry HandBook
IMPORTANT NOTES
131
CHAPTER
Chemistry HandBook
ALLEN
ALCOHOL (EAR)
Pd+H2 or LiAlH4/NaBH4 H2 O
GMP Hg(OAc)2 /H2O
CH2=CH2
CH3MgX
CH3–CH–CH3
LiAlH4
CH3 | CH3— C—CH=CH2 | CH3
H2O2/NaOH
(1° Alc.)
dil. H2SO4
CH3 | C—CH—CH3 CH— 3 | | OH CH3 (3° Alc.)
Hg(OAc)2/H2 O NaBH4
CH3 | CH3— C— CH—CH3 | | CH3OH (2° Alc.)
Å
O
OH 2° H3C C CH3 H
O CH2 CH2
Grignard Reagent
CH3—C—H H3O
OH | 3°CH3—C—CH3 | CH3
+
H3O
CH3MgBr
(NAR)
O2/60°C
(NAR)
O
O
O
O
CH3—C—Cl
H
(SNAE) Et2 O Mg (dry)
O Et
(SNAE)
C OEt (SNAE)
CH3—Br Aq. KOH Moist Ag2 O
• •
132
2CH3OH
H3O CH3 C
3
CH3 CH2 CH CH3
H3 O +
+
CH3 —C—CH3
3
OH
O
O
OH | CH MgBr 3°CH—C—CH + 3 3 HO | (NAR) CH3
CH—CH 2—CH—OH 2 3
+
CH2 CH CH3
(NSR)
O O MgBr H—C—H H3C C H + HO 3 H
(NSR)
+
(NAR)
1°CH3–CH2–OH
H3O
O
LiAlH4 H2 O
(ii) Zymase
(CH3)3C—CH—CH2 | | H OH
CH–C–OH 3
H2O
(i) Invertase
B2H6/THF
CH3–C–Cl O
OH R–OH
(NAR)
H2 O
C12H22O 11+H2O sucrose
CH–C–CH 3 3 O
LiAlH4/NaBH4 H2O
CH3–CH2–CH2–OH
H2O2/NaOH
CH3–CHO
H2O
CH3–CH2–OH
(EAR)
B2H6/THF
Pd+H2 or LiAlH4/NaBH4
CH3–OH
NaBH4
O CH3 C
O H3 C
C
OH CH3MgBr CH3 H O+ CH3 C CH3 3 CH3 (NAR)
H
CH3MgBr + H3O
(NAR)
H3C
CH OH
CH3
CH3—OH
Solubility of alcohol increase with increase in branching n < iso < neo (isomeric) Relative order of reactivity (i) 1° > 2° > 3° (O–H bond fission) (ii) 3° > 2° > 1° (C–O bond fission) (iii) 3° > 2° > 1° (Dehydration)
Z:\NODE02\B0B0-BA\HAND BOOK CHEMISTRY\ENG\3_ORGANIC.P65
CH2=CH2
CH–CHO 3
Reduction
Dil. H2SO4
CH2=CH2
E
CHAPTER
Chemistry HandBook
ALLEN
ALCOHOL
(NSR)
HCl+SO2+CH3—CH2—Cl + SO2+CH3—CH2—Cl
CH3—CH2—O—CH2—CH3 CH2=CH2
CH3MgBr
PCl3
CH4+CH3—CH2OMgBr
O
O
(SNAE) CH3—C—OH Conc. H2SO4
PBr3 SOCl2 SOCl2/
HI or KI/H3PO4
O (CH3—C)2O (SNAE) HCl/ZnCl2 Lucas Reagent
NH3 Al2O3
170°C
620 K
H2SO4
CH2=CH2
(Elimination)
(i) Na (ii) CH3—CH2—I (1°)
100°C
CH3—CH2—Br [3° R—O—H ® Alkene]
CH3—CH2—NH2
Al2O3 Conc. H 2SO4
O CH3—C—O—CH2—CH3 CH3—CH2Cl
HBr or NaBr + H2SO4
H2SO4/D/140°C
CH3—CH2HSO4
CH3—C—O—CH2—CH3
(NSR)
CH3—CH2—I
Å
CH3CH2—ONa
Estrification
H3PO3+3CH3—CH2—Br
Na
CH3—CH2—OH
H3PO3+3CH3—CH2—Cl
PCl5
Acid base reaction
POCl3+CH3—CH2—Cl
CH3CH2—O—CH2—CH3
DEHYDROGENATIONS OH H 3C
Reagent
H3C CH2 CH CH3
CH2 CH2 CH2
H3C CH2 CH2 C
Å
H
H3C CH2 C CH3 O
O H 3C C H 2 C H 2 C
Jo ne s Rea gent
OH
Z:\NODE02\B0B0-BA\HAND BOOK CHEMISTRY\ENG\3_ORGANIC.P65
O
No reaction No reaction
H3C–C–OH+CH3–C–OH
O
E
CH3 3° Alcohol
O
O
K 2C r2 O 7 / H KMnO 4 /H + /O H/ D
H3C–C–OH
2° Alcohol
1° Alcohol PCC/PDC Anhy. CrO3
CH3
OH
CH3
O
Cu/300°C
H3C CH2 CH2 C
Lucas Reagent HCl/ZnCl2
Cloudiness appear upon heating after 30 mins.
H
CH3 CH2
C
CH3
H3C
within five min.
CH2
C
Immediately
VICTOR MEYER'S TEST P/I2
CH3–CH2–CH2–CH2–I
CH3
CH3 H3C CH2 CH I
H3C
C
I
CH3
CH3
AgNO2
CH3–CH2–CH2–NO2
H3C HNO2
NaOH
CH2 C
NO2
CH2 CH
NO2
N OH Nitrolic acid
Red Color
H3C
(CH3)3C–NO2
CH3 H3 C
CH2 C N
NO2
(No reaction)
O
Blue colour
Colourless
133
C HAP TE R
Chemistry HandBook
ALLEN
GMP
Reactions
ETHER
2 C2H5 OH
H 2SO 4 /140°C
[Williamson continuous etherification]
Cl2 Dark
(NSR) [SN2] +
H3C CH2 ONa
[Williamson synthesis] [3°[R–X] ® Alkene]
CH 3—CH 2—I
(NSR) [SN 2]
HCl
H3C CH2 O CH2 CH3
Cold
H3C CH2 O CH3 Dry Ag2O
2C2H5I
CH 2N 2/BF3 ,
CH3—CH2—OH
D
SO3Na (i) NaOH (ii) H
HI/cold
R O R
(NSR)
HI/D excess
GMP
Å
(i) O2 + D (ii) H Å/H2O
CH3 H3C C H
(–CH3COCH3) other product
+
N2Cl
H2O/D
OH Cl H 2O Industrial method
(i) O2/60°C/D (ii) H 2O/H
COOH OH
+
PHENOL H
NaOH+CaO/D
O 2, V2O5 300°C
OCH3 Br +
OCH3 CH3 +
OCH3 Br2 in CH3COOH Bromination
CH3COCl AlCl3
AlCl3 /CH3Cl Friedel-crafts reaction
OCH3
Friedel-Crafts reaction
Br OCH3
CH3
134
OCH3
OCH3 COCH3 +
conc. H2SO4
Anisole
conc. HNO3
OCH3 NO2
COCH3 OCH3 +
(nitration)
NO2
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MgBr
E
C HAP TE R
Chemistry HandBook
ALLEN
O
60°C
C
OH
CH3
PHENOL
O
Fries Rearrangement
O C CH3 H3C
C
O Na+
Reactions
O Cl
NaOH
CH3I
SNAE
H—O C CH3
O CH3
120°C
OH NH2
O
O CH3
CH2N2 BF3
NH3
H
ZnCl 2/300°C Zn
3HCl+ [(Ph3O)6Fe]3Violet Colour
No effervescence
FeCl3 Neutral
D
Cl
PHENOL PCl5
NaHCO3
+ (Ph O)3PO
(major) Triphenyl phosphate
O
+ ONa
Ph
NaOH Na2CO3
C
O O C Ph
Cl
Schotten Baumann Reaction
O
OH O2N
NO2
+ O
OH
Conc. HNO3+H2SO4
NaOH Blue
N O
OH O C
Kolbes Schimdt Reaction
OH
H2SO4 Libermann nitroso test
125°C CO2/NaOH H
+
OH HO C O
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N N
E
CCl4 NaOH
OH
O C
OMe
MeOH Å
H
OH O C
Oil of wintergreen O
Ac C OH O
Aspirin
Å
N NCl
Orange dye
HO
Mild basic medium
O
CH3–C–Cl
O
OH
CO2/NaOH 125°C
O O
O
O
Na2Cr2O7 H2SO4
OH Br
+
CS2
NaNO2
H2SO4
Green
OH
Br2
REACTION DUE TO BENZENE RING
excess
HNO3
NO2
OH H2 O
2,4,6-Tribromophenol (White ppt) Br
OH
Red
Br
H2O
NO2
(major)
Br
Br2
Br
OH
OH
conc. HNO3
SO3 H
Conc. H2SO4
O2N
100°C
NO2
NO2
SO3H OH Å CH2 =O + H
OH CH2OH
+
NaOH D
Bakelite polymer
CH OH 2
OH O C
CHCl3
H Reimer Tiemann Reaction
NaOH
HCN+HCl
OH O C
OH H
H3O+ O
Gatterman Reaction
CHO
(major)
C C
+
O
O conc. H2SO4
CO2/NaOH 125°C/H +
Phenolphthalein
OH O C
NaOH
(Pink colouration)
OH Ph-OH POCl3
Phenyl salicylate
135
C HAP TE R
Chemistry HandBook
ALLEN
A
REACTIONS Kinetics
Comparision of E1 and E2
SN1 1st order
SN2 2nd order
REACTIONS A Kinetics B C
B
Rate
k[RX]
k[RX][Nu:Q]
C
Stereochemistry
Racemisation
Inversion
D
3°> 2°>1°>MeX
MeX >1°>2°>3°
E
Substrate (reactivity) Nucleophile
F
Solvent
Rate Independent Good in protic
Needs Strong Nu Faster in aprotic
G
Leaving Group
Needs Good LG
Needs Good LG
H
Rearrangement
Possible
Not Possible
E1 1 order
E2 2 order
Rate
k[RX]
Stereochemistry
No special geometry 3° > 2°>>>1°
k[RX][B: ] Antiperiplanar 3° >2° >1°
D
Substrate
E
Base Strength
F
Solvent
G
Leaving Group
H
Rearrangement
Summary of SN1, SN2, E1 and E2 Reactions RX 1°
Mechanism S N2 E2
2°
3°
Q
Q
Nu / B
Better NuQ Aq. KOH, ORQ Strong & bulky base Alc. KOH, (CH3)3COQ
Polar aprotic
Temp. Low
nd
—
Rate Independent Good ionizing
Needs Strong bases Polarity not import Needs Good LG Not Possible
Needs Good LG Possible
Order of reactivity of Alkyl Halide towards S N1 µ Benzylic > Allylic > 3°>2°>1°
High
SN1 µ Stability of carbocation
Low
SN2 µ 1° > 2° > 3°
S N2
Aq. KOH
E2
ORQ , (CH3)3COQ
(SN1)
Solvent
(E1)
Solvent
S N1
Solvent
Protic
Low
R–I > R–Br > R–Cl > R–F
E1
Solvent
Protic
High
E2
NuQ/Base
—
High
With increase in number of strong electron withrawing
Primary (1°)
136
Solvent
st
Polar aprotic Polar protic
Secondary (2°) SN2 + E2 (if weak base, SN2 favored)
High (Low) (High)
Tertiary (3°)
Strong nucleophile
SN2 >>E2
Weak nucleophile weak base
Mostly SN2
Mostly SN2/SN1
Mostly SN1 at low T mostly E1 at high T
Weak nucleophile strong base
Mostly E2
Mostly E2
E2
E2
SN2 µ
1 Steric hindrance
Reactivity order towards SN1 or SN2 and E1 or E2
group at ortho and para position, reactivity of X towards aromatic nucleophilic substitution increases. Cl
Cl
Cl NO2