CHEMISTRY PAPER-I (Inorganic Chemistry): 200 Marks
Chemical periodicity:
Periodic table, group trends and periodic trends in physical properties. Classification of elements on the basis
of electronic configuration. Modern IUPAC Periodic table. General characteristic of s, p, d and f block elements.
Effective nuclear charges, screening effects, atomic radii, ionic radii, covalent radii. Ionization potential, electron
affinity and electro-negativity. Group trends and periodic trends in these properties in respect of s-, p- and d-block
elements. General trends of variation of electronic configuration, elemental forms, metallic nature, magnetic
properties, catenation and catalytic properties, oxidation states, aqueous and redox chemistry in common oxidation
states, properties and reactions of important compounds such hydrides, halides, oxides, oxy-acids, complex
chemistry in respect of s-block and p-block elements.
Chemical Bonding and structure:
Ionic bonding: Size effects, radius ratio rules and their limitations. Packing of ions in crystals, lattice energy, Bornlande
equation and its applications, Born-Haber cycle and its applications. Solvation energy, polarizing power
and polarizability, ionic potential, Fazan's rules. Defects in solids. Covalent bonding: Lewis structures, formal
charge. Valence Bond Theory, Molecular orbital Theory, hybridizations, VSEPR theory. Partial ionic Character of
covalent bonds, bond moment, dipole moment and electro negativity differences. Concept of resonance,
resonance energy, resonance structures. Schrodinger equation for the H-atom.
Coordinate bonding: Werner theory of coordination compounds, double salts and complex salts, Lewis acid-base.
Ambidentate and polydentate ligands, chelate complexes. IUPAC nomenclature of coordination compounds.
Coordination numbers, Geometrical isomerism. Stereoisomerism in square planar and octahedral complexes.
Hydrogen bonding. Metallic bonding: qualitative idea of band theory, conducting, semi conducting and insulating
properties.
Chemistry of coordination compounds:
Isomerism, reactivity and stability: Determination of configuration of cis- and trans- isomers by chemical methods.
Labile and inert complexes, substitution reaction on square planer complexes, trans effect. Stability constants of
coordination compounds and their importance in inorganic analysis. Structure and bonding: Elementary Crystal
Field Theory: splitting of do configurations in octahedral, square planar and tetrahedral fields, crystal field
stabilization energy; pairing energy. Jahn- Teller distortion. Metal-ligand bonding, sigma and pi bonding in
octahedral complexes and their effects on the oxidation states of transitional metals . Orbital and spin magnetic
moments, spin only moments of and their correlation with effective magnetic moments, d-d transitions; LS
coupling, spectroscopic ground states, selection rules for electronic spectral transitions; spectro-chemical series
of ligands; charge transfer spectra .
Acid-Base reactions
Acid-Base concept: Arrhenius concept, theory of solvent system, Bronsted-Lowry's concept, relative strength of
acids, Pauling rules. Lewis concept. Acidbase equilibria in aqueous solution and pH. Acid-base neutralisation curves;
indicator, choice of indicators.
Precipitation and Redox Reactions:
Solubility product principle, common ion effect. Ion-electron method of balancing equation of redox reaction.
Standard redox potentials, Nernst equation. Influence on complex formation, precipitation and change of pH on
redox potentials; formal potential. Feasibility of a redox titration, redox potential at the equivalence point, redox
indicators. Redox potential diagram of common elements and their applications. Disproportionation and
comproportionation reactions.
Organo metallic compounds:
18-electron rule and its applications to carbonyls, nitrosyls, cyanides, and nature of bonding involved therein.
Simple examples of metal-metal bonded compounds and metal clusters. Metal-olefin complexes: zeises salt,
Ferrocene.
Nuclear chemistry:
Radioactive decay - General characteristics, decay kinetics, parent -daughter decay growth relationships,
determination of half-lives, Nuclear models -shell model, liquid drop model, Fermi gas model, Collective model
and optical model. Nuclear stability. Decay theories. Nuclear reactions- fission, fusion and spallation reactions.
Definition of curie and related calculations, preparation of artificial radionuclides by bombardment,
radiochemical separation techniques. Experimental techniques in the assay of radioisotopes, gas filled detectorsionization
chamber, proportional and Geiger-Muller counters -G.M. Plateau, dead time, coincidence loss,
determination of dead time, scintillation counters, solid state detectors.
s-Block Elements :
Hydride , hydration energies, solvation and complexation tendencies of alkali and alkaline-earth metals, principle of
metallurgical extraction, Chemistry of Li and Be, their anomalous behaviour and diagonal relationships, alkyls
and aryls.
p-Block Elements :
Comparative study of group 13 & 14 elements with respect to periodic properties. Compounds such as hydrides,
halides, oxides and oxyacids; diagonal relationship; preparation, properties, bonding and structure of diborane,
borazine and alkalimetal borohydrides. Preparation, properties and technical applications of carbides and fluorocarbons.
Silicones and structural principles of silicates.
Chemistry of d- and f- block elements:
General comparison of 3d, 4d and 5d elements in term of electronic configuration, elemental forms, metallic nature,
atomization energy, oxidation states, redox properties, coordination chemistry, spectral and magnetic properties. fblock
elements: electronic configuration, ionization energies, oxidation states, variation in atomic and ionic (3+)radii, magnetic and spectral properties of lanthanides, comparison between lanthanide and actinides, separation
of lanthanides (by ion-exchange method). Chemistry of some representative compounds: K2Cr2O7, KMnO4,
K4[Fe(CN)6], K2[Ni(CN)4], H2PtC16, Na2[Fe(CN)5N0].
CHEMISTRY PAPER-II (Physical Chemistry) :200
Kinetic theory and the gaseous state:
Gaseous state: Gas laws, kinetic theory of gas, collision and gas pressure, derivation of gas laws from kinetic
theory, average kinetic energy of translation, Boltzmann constant and absolute scale of temperature. Maxwell's
distribution of speeds. Kinetic energy distribution, calculations of average, root mean square and most probable
velocities. Principle of equipartition of energy and its application to calculate the classical limit of molar heat
capacity of gases.
Collision of gas molecules, Real gases:
Collision diameter; collision number and mean free path; frequency of binary collisions; wall collision and rate of
effusion. Real gases, Deviation of gases from ideal behaviour; compressibility factor; Andrew's and Amagot's plots;
van der Waals equation and its characteristic features. Existence of critical state. Critical constants in terms of
van der Waals constants. Law of corresponding state and significance of second virial coefficient. Boyle
temperature. Intermolecular forces.
Liquid state: physical properties of liquids and their measurements: surface tension and viscosity
Solids: Nature of solid state, law of constancy of angles, concept of unit cell, different crystal system, Bravais
lattices, law of rational indices, Miller indices, symmetry elements in crystals. X-ray diffraction, Bragg's law,
Laue's method, powder method, radius ratio and packing in crystals.
Thermodynamics:
Definition of thermodynamic terms. Thermodynamic functions and their differentials. Zeroth law, First law and
Second law of thermodynamics. Cyclic, reversible and irreversible processes. Internal energy (U) and enthalpy (H);
relation between Cp and Cv, calculation of w, q, ?U and ?H for expansion of ideal gas under isothermal and adiabatic
conditions for reversible and irreversible processes including free expansion. Joule-Thomson Coefficient
and inversion temperature. Application of First law of thermodynamics.
Application of Second law of thermodynamics.
Carnot cycle and its efficiency, Gibbs function (G) and Helmholtz function (A), Gibbs-Helmholtz equation, criteria
for thermodynamic equilibrium and spontaneity of a process.
Chemical equilibrium: chemical equilibria of
homogeneous and heterogeneous systems, derivation of expression of equilibrium constants, Le Chatelier's principle
of dynamic equilibrium.
Thermodynamics and Equilibrium:
Chemical potential in terms of Gibb's free energy and other thermodynamic state functions and its variation with
temperature and pressure. Gibbs-Duhem equation; fugacity of gases and fugacity coefficient. Thermodynamic
conditions for equilibrium, degree of advancement. Van't Hoffs reaction isotherm. Equilibrium constant and
standard Gibbs free energy change. Definitions of KP, KC and Kx; van't Hoffs reaction isobar and isochore. Le
Chatelier's principle. Activity and activity coefficients of electrolyte / ion in solution. Debye-Huckel limiting law.
Acids-bases and solvents:
Modern aspects of acids and bases: Arrhenius theory, theory of solvent system, Bronsted and Lowry's concept,
Lewis concept with typical examples, applications and limitations. Strengths of acids and bases. Ionization of weak
acids and bases in aqueous solutions, application of Ostwald's dilution law, ionization constants, ionic product of
water, pH-scale, buffer solutions and their pH values, buffer actions & buffer capacity; hydrolysis of salts.
Solutions of non-electrolytes: Colligative properties of solution, Raoult's Law, relative lowering of vapor
pressure, osmosis and osmotic pressure; elevation of boiling point and depression of freezing point of solvents.
Chemical kinetics and catalysis:
Order and molecularity of reactions, rate laws and rate equations for first order and second order reactions; zero
order reactions. Parallel and consecutive reactions. Determination of order of reactions. Temperature
dependence of reaction rate, energy of activation. Enthalpy of activation, entropy of activation , effect of dielectric
constant and ionic strength of reaction rate, kinetic isotope effect; collision theory & transition State Theory of
reaction rate, Catalytic reactions.
Adsorption and Surface Chemistry:
Physisorption & Chemisorption, adsorption isotherms, Freundlich and Langmuir adsorption isotherm, BET
equation, surface area determination, heterogeneous catalysis; colloids, electrical double layer and colloid stability,
electro-kinetic phenomenon; elementary ideas about soaps & detergents, micelles, emulsions.
Electrochemistry:
Conductance: cell constant, specific conductance and molar conductance. Kohlrausch's law of independent migration of ions, ion
conductance and ionic mobility. Equivalent and molar conductance at infinite dilution. Ostwald's dilution law. Debye-Huckel theory. Application of conductance measurement. Conductometric titrations. Determination of transport number by moving
boundary method. Types of electrochemical cells, cell reactions, emf and change in free energy, 6.H and AS of
cell reactions. Nernst equation. Standard cells. Half-cells /electrodes, different types of electrodes. Standard
electrode potential and principles of its determination. Types of concentration cells. Liquid junction potential.
Glass electrode and determination of pH of a solution. Potentiometric titrations: acid-base and redox, electro
chemical power sources; primary, secondary and fuel Cells, corrosion and inhibition of corrosion.
Photochemistry :
Frank-Condon principle and vibrational structure of electronic spectra. Bond dissociation and principle of
determination of dissociation energy. Decay of excited states by radiative and non-radiative paths. Fluorescence
and phosphorescence, Jablonsky diagram. Laws of photochemistry: Grotthus-Draper law, Stark-Einstein law of
photochemical equivalence and Lambert-Beers law; quantum yield and its measurement for a photochemical
process, actinometry. Photostationary state. Photosensitized reactions. Kinetics of HI decomposition, H2-Br2
reaction, dimerisation of anthracene.
Quantum Chemistry:
Wave-particle duality, Photoelectric and Compton effects, de Broglie hypothesis. Eigenfunctions and
eigenvalues. Uncertainty relation, Expectation value. Hermitian operator. Schrodinger time-independent
equation: nature of the equation, acceptability conditions imposed on the wave functions and probability
interpretations of wave function. Schrodinger equation for one-dimensional box and its solution. Comparison with
free particle eigenfunctions and eigenvalues.
Basic principles and application of spectroscopy:
Electromagnetic radiation, interaction with atoms and molecules and quantization of different forms of energies.
Condition of resonance and energy of absorption for various types of spectra; origin of atomic spectra, spectra of
hydrogen atoms, many electron atoms, spin and angular momentum. Rotational spectroscopy of diatomic molecules:
rigid rotor model, selection rules, spectrum, characteristic features of spectral lines. Determination of bond
length, effect of isotopic substitution. Vibrational spectroscopy of diatomic molecules: Simple Harmonic Oscillator
model, selection rules, Raman Effect. Characteristic features and conditions of Raman activity with suitable
illustrations. Rotational and vibrational Raman spectra.
UV Spectra: Electronic transition (a-a*, n-u*, IT-1T" and n-n'), relative positions of Amax considering
conjugative effect, steric effect, solvent effect, red shift (bathochromic shift), blue shift (hypsochromic shift),
hyperchromic effect, hypochromic effect (typical examples). IR Spectra: Modes of molecular vibrations, application
of Hooke's law, characteristic stretching frequencies of O-H, N-H, C-H, C-D, C=C, C=N, C=0 functions; factors
effecting stretching frequencies
PMR Spectra: Nuclear spin, NMR active nuclei, principle of proton magnetic resonance, equivalent and nonequivalent
protons, chemical shift ?), shielding / deshielding of protons, up-field and down-field shifts. NMR peak
area, diamagnetic anisotropy, relative peak positions of different kinds of protons, substituted benzenes.
CHEMISTRY PAPER-III:200 Marks
PART-A (Analytical Chemistry): 100 Marks
Theoretical basis of Quantitative inorganic analysis:
Law of mass action, chemical and ionic equilibrium, solubility, Solubility product and common ion effect, effect of
temperature upon the solubility of precipitates, the ionic product of water, pH, effect of temperature on pH, Salt
hydrolysis, hydrolysis constant, degree of hydrolysis, buffer solutions, different types of buffers and Henderson's
equation.
Gravimetric Analysis:
General principles, stoichiometry, calculation of results from gravimetric data. Properties of precipitates.
Nucleation and crystal growth, factors influencing completion of precipitation. Co-precipitation and postprecipitation,
purification and washing of precipitates. Precipitation from homogeneous solution, a few common
gravimetric determinations-chloride as silver chloride, sulphate as barium sulphate, aluminum as the oxinate
and nickel as dimethyl glyoximate.
Sampling and treatment of samples for chemical analysis:
Techniques of collection of Solids, liquids and gaseous samples, dissolution of solid samples, attack with water,
acids, and alkalis, fusion with Na2CO3, NaOH, Na202, K2S207; Microwave assisted digestion techniques(Only
elementary idea) Volumetric Analysis:
Equivalent weights, different types of solutions, Normal solutions, Molar solutions, and molal solutions and their
inter relations. Primary and secondary standard substances. principles of different type of titrations-i) acid-base
titration, ii) redox titration, iii) complexometric titrations. Types of indicators - i) acid-base, ii) redox iii) metal-ion
indicators. Principles in estimation of mixtures of NaHCO3 and Na2CO3 (by acidimetry); Principles of estimation
of iron, copper, manganese, chromium (by redox titration);
Acid base titrations: Principles of titrimetric analysis, titration curves for strong acid-strong base, weak acid-strong
base and weak base-strong acid titrations, poly protic acids, poly equivalent bases, determining the equivalence
point-theory of acid base indicators, colour change range of indicator, selection of proper indicator.
Redox Titrations: Principles behind the lodometry, permaganometry, dichrometry, difference between iodometry
and iodimetry.
Potentiometry: Fundamentals of potentiometry. indicator and ion-selective electrodes. Membrane electrodes.
Glass electrode for pH measurement, glass electrodes for cations other than protons. Liquid membrane
electrodes, solid state ion selective detectors and biochemical electrodes. Applications of potentiometry. Direct
potentiometric measurements-determination of pH and fluoride. Redox and potentiometer titrations- Balancing
redox reactions, calculation of the equilibrium constant of the reaction, titration curves, visual end point
detection. Redox indicators-theory, working and choice. Potentiometric end point detection. Applications of
redox titrations.
Complexometric titrations: Complex formation reactions, stability of complexes, stepwise formation constants,
chelating agents, EDTA-acidic properties, complexes with metal ions, equilibrium calculations involving EDTA,
conditional formation constants, derivation of EDTA titration curves, effect of other complexing agents, factors
affecting the shape of titration curves-completeness of reaction, indicators for EDTA titrations-theory of common
indicators, titration methods employing EDTA-direct, back and displacement titrations, indirect determinations,
titration of mixtures, selectivity, masking and de-masking agents, typical applications of EDTA titrations-hardness
of water, magnesium and aluminium in antacids, magnesium, manganese and zinc in a mixture, titrations involving
uni-dentate ligands-titration of chloride with Hg2+ and cyanide with Ag+.
Chromatographic methods of analysis:
Basic principles and classification of chromatography. Importance of column chromatography and thin
layer chromatography; Theory and principles of High Performance Liquid Chromatography (HPLC) and Gas
Liquid Chromatography (GLC). Ion-exchange chromatography.
UV-Visible Spectroscopy:
Basic Principles of UV-Vis spectrophotometer. Lambert -Beer's Law and its limitations. Instrumentation consisting
of source, monochromator, grating and detector. Spectrophotometric determination.
Flame photometry and Atomic absorption spectrometry:
Emission spectra Vs absorption spectra. Basic Principles and theory of flame photometry. Applications of Flame
photometers. Basic Principles and theory of AAS. Three different modes of AAS - Flame-MS, VGAAS, and GFAAS.
Single beam and double beam AAS. Function of Halo Cathode Lamp (HCL) and Electrode Discharge Lamp
(EDL). Different types of detectors used in MS. Different types of interferences-Matrix interferences, chemical
interferences, Spectral interferences and background correction in AAS. Use of organic solvents. Quantitative
techniques-calibration curve procedure and the standard addition technique. Typical commercial instruments for
FP and MS. Applications. Qualitative and qualitative analysis. Relative detection abilities of atomic absorption
and flame emission spectrometry.
X-ray methods of Analysis:
Introduction , theory of X-ray generation, X-ray spectroscopy, X-ray diffraction and X-ray fluorescence methods,
Braggs law, instrumentation , dispersion by crystals, applications. Preparation of pallets, glass beads, quantitative
and qualitative measurement.
Inductively coupled plasma spectroscopy:
Theory and Principles, plasma generation, utility of peristaltic pump, sampler - skimmer systems, ion lens,
quadrupole mass analyzer, dynode /solid state Detector, different type of interferences- spectroscopic and nonspectroscopic
interferences, isobaric and molecular interferences, applications.
Analysis of Minerals, Ores and Alloys:
Analysis of Minerals and Ores- estimation of (i) CaCO3 , MgCO3 in dolomite (ii) Fe203, Al203, and TiO2 in
Bauxite.(iii) MnO and Mn02 in Pyrolusite.
Analysis of Metal and Alloys: (i) Cu and Zn in Brass (ii) Cu, Zn, Fe, Mn, Al and Ni in Bronze (iii) Cr, Mn, Ni, and P in
Steel (iv) Pb, Sb, Sn in type metal.
Analysis of petroleum and petroleum products:
Introduction, constituents and petroleum fractionation. Analysis of petroleum products-specific gravity, viscosity,
Doctor test, aniline point, colour determination, cloud point, pour point. Determination of water, neutralization
value (acid and base numbers), ash content, Determination of lead in petroleum.
Analysis of coal and coke-Types, composition, preparation of sample, proximate and ultimate anlaysis calorific
value by bomb Calorimetry.
PART-B (Organic Chemistry): 100 Marks
Basic organic chemistry:
Inductive effect, resonance and resonance energy. Homolytic and heterolytic bond breaking, electrophiles and
nucleophiles; carbocations, carbanions and radicals (stability and reactivity). Alkanes, alkenes and alkynes:
Synthesis and chemical reactivity of alkanes, mechanism of free-radical halogenation of alkanes. General methods
of synthesis, electrophilic addition reactions and polymerization reaction (definition and examples only) of alkenes.
General methods of synthesis, acidity, hydration and substitution reactions of alkynes.
Organometallic compounds:
Grignard reagents - preparations and reactions, application of Grignard reagents in organic synthesis. Organic
compounds containing nitrogen: aromatic nitro compounds - reduction under different conditions. Methods of
synthesis of aliphatic amines, Heinsberg's method of amine separation, Hofmann degradation, Gabriel's phthalimide
synthesis, distinction of primary, secondary and tertiary amines; methods of synthesis of aromatic amines, basicity
of aliphatic and aromatic amines. Sandmeyer reactions; synthetic applications of benzene diazonium salts.
Bonding and physical properties:
Valence bond theory: concept of hybridisation, resonance (including hyperconjugation), orbital pictures of
bonding sp3, sp2, sp: C-C, C-N & C-0 system). Inductive effect, bond polarization and bond polarizability, steric
effect, steric inhibition of resonance. MO theory: sketch and energy levels of MOs of i) acyclic p orbital system ii)
cyclic p orbital system, iii) neutral system. Frost diagram, Huckel's rules for aromaticity & antiaromaticity;
homoaromaticity. Physical properties: bond distance, bond angles, mp/bp & dipole moment in terms of
structure and bonding. Heat of hydrogenation and heat of combustion.
Aldol and related reactions:
Keto-enol tautomerism, mechanism and synthetic applications of aldol condensations, Claisen reaction, Schmidt
reaction, Perkin reaction, Knovenogal, benzoin, Cannizaro reaction, Michael addition. Aromatic substitution reactions -
electrophilic, nucleophilic and through benzynes - radical substitution of arenes - orientation of nucleophilic
substitution at a saturated, carbon, SN1, SN2, SNi reactions -effect of structure, nucleophile, leaving group, solvent.
Additions involving electrophiles, nucleophiles and free radicals.
Mechanism of some name reactions:
Aldol, Perkin, Benzoin, Cannizaro, Wittig, Grignard, Reformatsky, Hoffmann, Claisen and Favorsky
rearrangements. Openauer oxidation, clemmensen reduction, Meerwein - Pondorf and Verley and Birch
reductions. Stork enamine reactions, Michael addition, Mannich Reaction, Diels - Alder reaction.
Electrocyclic Reactions:
Molecular orbital symmetry, frontier orbitals of ethylene, 1,3 Butadiene, 1,3,5- Hexatriene, ally! system,
classfication of pericyclic reactions FMO approach, Woodwrd- Hoffman correlation diagram method and
perturbation of molecular (PMO) approach for the explanation of pericyclic reactions under thermal and
photochemical conditions. Conrotatory and disotatory motions (4n) and (4n+2).
Organic Reaction Mechanisms:
Addition Elimination Mechanisms: (a) Addition to carbon multiple bonds- hydrogenation of double and triple
bonds, hydroboration, birch reduction, Michael reaction, addition of oxygen and N, (b) Addition to carbon-hetero
atom multiple bonds: Mannich reaction,Reductions of Carbonyl compounds, acids, esters, nitrites, addtion of
Grignard reagents, Reformatsky reaction, Tollen's reaction, Wittig reaction: (c) Elimination reactions:
Stereochemistry of eliminations in acyclic and cyclic systems, orientation in eliminations - Saytzeff and Hoffman
elimination.
Organic Spectroscopy:
Infrared spectroscopy: Units of frequency wave length and wave number, molecular vibrations, factors influencing
vibrational frequencies, the IR spectrometer, characteristic frequencies of organic molecules and interpretation
of spectra. Ultraviolet spectroscopy: Introduction, absorption laws, measurement of the spectrum,
chromophores, definitions, applications of UV spectroscopy to Conjugated dines, trienes, unsaturated carbonyl
compounds and aromatic compounds.
Nuclear Magnetic Resonance Spectroscopy: (Proton and Carbon -13
NMR) The measurement of spectra, the chemical shift: the intensity of NMR signals and integration factors affecting
the chemical shifts: spin-spin coupling to 13C IH-IH first order coupling: some simple IH-IH splitting patterns: the
magnitude of IH-IH coupling constants.
Mass spectroscopy: Basic Principles: instrumentation: the mass spectrometer, isotope abundances; the molecular
ion, meta stable ions.