About the Msc Chemistry
M.Sc. Program At the Department of Chemistry (Centre for Advanced Studies in Chemistry) University of Pune In collaboration with National Chemical Laboratory

Eligibility for Entrance

: The candidate from the open category with 50% marks and reserved category with 45% and having Chemistry/ Biochemistry as one of the subjects at T. Y. B. Sc. Level can apply. [Candidate appearing for the final year exam can also apply.

Reservation of Seats :
50 % seats are reserved for SC, ST, DTNT and OBC will be followed as per the Government of Maharashtra Rules (applicable only to the candidates of Maharashtra state) 3% seats are reserved for Physically Handicapped Students as per Government of Maharashtra rules.

Syllabus of the MSc Chemistry Entrance Exam

Physical Chemistry:
Chemical kinetics:
Basics of atomic structure:
Electrolytic conductance:
Thermodynamics:
Surface Chemistry:
Phase rule: Definitions,
Nuclear chemistry:
Crystal structure:
Electrochemical cells:
Photochemistry

Inorganic Chemistry:

Molecular Orbital Theory:
Co-ordination chemistry.
Chemistry of the main group elements and their compounds:
Chemistry of transition elements and coordination compounds:
Metals,
Ionic Solids:
Heterogenous and homogenous catalysis.
Analytical chemistry:
Bioinorganic chemistry:

rest of the syllabus you may get from the below Attachement that is Free to Download

MSc Chemistry Entrance Exam syllabus


Syllabus for the MSc. Chemistry Entrance Examination
Physical Chemistry:
1. Basic principles and applications of quantum mechanics: particle in one dimensional box,
hydrogen atom, angular momentum.
2. Chemical kinetics: order, molecularity, methods to determine order of reaction using
integrated rate equation, zero, first, second and half integral order reactions, determining
the order- graphical method, half-life method, differential method, effect of temperature on
reaction rate, Arrhenius equation, related numericals.
3. Basics of atomic structure: electronic configuration, shapes of orbitals, hydrogen atom
spectra.
4. Electrolytic conductance: Electrolytic conductance, specific and equivalent conductance,
variation of equivalent conductance with concentration, Kohlrausch’s law and its
applications.
5. Thermodynamics: Zero, first, second and third law of thermodynamics- enthalpy, entropy,
free energy and their dependence on pressure and temperature.
6. Surface Chemistry: adsorption, physisorption and chemisorption, Freundlich and Langmuir
adsorption isotherms, surface area determination.
7. Phase rule: Definitions, Gibb’s phase rule, one component system (moderate pressure only)
for sulphur and water system, two component system for silver-lead and zinc-cadmium.
8. Nuclear chemistry: The atom, nucleus and outer sphere, classification of nuclides, nuclear
stability and binding energy, discovery of radioactivity, types of radioactivity, general
characteristics of radioactive decay and decay kinetics, measurements radioactivity,
gaseous ion collection method, proportional and G.M. counter, applications of
radioactivity, radiochemical principles in the use of tracers, typical applications of
radioisotopes as a tracer.
9. Crystal structure: Crystallization and fusion process, crystallography, crystal systems,
properties of crystals, crystal lattice and unit cell, crystal structure analysis by X ray, The
Laue’s method and Bragg’s method, X-ray analysis of NaCl crystal system, calculation of
d and λ for a crystal system.
10. Electrochemical cells: Reversible and irreversible cells, EMF and its measurements,
standard cells, cell reaction and EMF, single electrode potential and its calculation,
calculation of cell EMF, thermodynamics of cell EMF, types of electrodes, classification
of electrochemical cells with and without transference, applications of EMF measurement
i) Solubility product of sparingly soluble salt, ii) Determination of pH, iii) Potentiometric
titration.
11. Photochemistry: Introduction, thermal reactions and photochemical reactions, laws of
photochemistry, quantum yield, measurement of quantum yield, types of photochemical
reactions, photosynthesis, photolysis, photocatalysis, photosensitization, photophysical
process, fluorescence, phosphorescence, quenching, chemiluminescence.
Inorganic Chemistry:
1. Molecular Orbital Theory: Limitations of Valence Bond theory (VBT), need of Molecular
Orbital Theory (MOT), features of MOT, formation of molecular orbitals (MO’s) by LCAO
principle, rules of LCAO combination, different types of combination of Atomic orbital
(AO’s): σ, π and δ MOs, Non-bonding combination of orbitals (formation of NBMO), M.O.
energy level diagram for homonuclear diatomic molecules, bond order and existence of
molecule from bond order.
2. Co-ordination chemistry: Coordinate bond, central metal atom or ions, ligand, double salt,
complex compound, coordination number, charge on the complex ion, oxidation number
of metal ion, first and second coordination sphere, ligands: definition, classification,
chelates and chelating agents, formation constant, inert and labile complexes, IUPAC
nomenclature of coordination compounds, different geometries of coordination compounds
with C.N.= 4 to C.N.=10 and examples of each geometry.
3. Chemistry of the main group elements and their compounds: Allotropy, synthesis, bonding
and structure.
4. Chemistry of transition elements and coordination compounds: Bonding theories, spectral
and magnetic properties, reaction mechanisms.
5. Metals, semiconductors and Super conductors: Metallic bonding, band theory in metals
with respect to Na along with n (E) and N(E) diagrams, Electrical conductivity of metals
(Na, Mg, Al), valence electrons and conductivity.
6. Ionic Solids: Crystalline and amorphous solids, crystal structures, simple cubic, body
centered cubic and face centered cubic, properties of ionic solids, packing arrangements of
anions in an ionic solids, voids in crystal structure, tetrahedral and octahedral, ionic radius,
Pauling’s univalent and crystal radii, conversion of univalent radii to crystal radii, problems
based on conversion of radii, radius ratio effect, Lattice energy, Born-Lande equation, Born
Haber cycle and its applications, Schottky and Frenkel defect.
7. Heterogenous and homogenous catalysis.
8. Analytical chemistry: Separation techniques, spectroscopic electro- and thermoanalytical
methods.
9. Bioinorganic chemistry: Photosystems, porphyrines, metalloenzymes, oxygen transport,
electron-transfer reactions, nitrogen fixation.
Organic Chemistry:
1. IUPAC nomenclature of organic compounds.
2. Strength of organic acids and bases: pKa, origin of acidity, influence of solvent, simple
aliphatic saturated and unsaturated acids, substituted aliphatic acid, phenols, aromatic
carboxylic acids, pKa and temperature, pKb, aliphatic and aromatic bases, heterocyclic
bases, acid base catalysis.
3. Stereochemistry of disubstituted cyclohexane: 1,1-alkyl disubstituted cyclohexane;
Dimethyl cyclohexane 1,2; 1,3 and 1,4; geometrical isomerism, optical isomerism, stability
of conformation, energy calculations.
4. Nucleophilic substitution at aliphatic carbon: The SN1
reaction: kinetics, mechanism and
stereochemistry (Racemization), stability of carbocation. The SN2
reaction: Kinetics,
mechanism & stereochemistry (inversion), SNi reaction and mechanism.
5. Reactions of unsaturated hydrocarbons and carbon oxygen double bond: Mechanism of
electrophilic addition to C=C bond, orientation & reactivity, rearrangements, (support for
formation of carbocation), addition of hydrohalogen, Anti Markownikoff’s addition
(peroxide effect) with mechanism, addition of halogens (dl pairs and meso isomers),
hypohalous acids (HOX), hydroxylation (mechanism of cis and trans 1,2-diols),
hydroboration- oxidation (formation of alcohol), hydrogenation (formation of alkane),
ozonolysis (formation of aldehydes & ketones).
6. Elimination reactions: 1,1; 1,2 elimination, E1, E2 and E1cB mechanism with evidences,
Hoffmann and Saytzeff’s elimination, reactivity effect of structure, attacking and leaving
groups.
7. Aromatic Electrophilic and Nucleophilic Substitution reactions: Arenium ion mechanism,
effect of substituent group (orientation, o/p directing and meta directing groups).
classification of substituent groups (activating and deactivating groups), mechanism of –
nitration, sulfonation, haloganation, Fridel-Crafts reactions, Diazo Coupling reactions,
Ipso-substitution, Addition-elimination (SNAr), SN1
, Elimination-addition (Benzyne)
SNR1 reactions, reactivity.
8. Carbanions and their reactions: Reactions involving carbanions and their mechanisms:
Aldol, Claisen, Dieckmann and Perkin condensations. Synthesis and Synthetic applications
of Malonic ester, Acetoacetic ester and Wittig reagent.
9. Retrosynthetic analysis and applications: Retrosynthesis and synthesis of target molecules:
Acetophenone, Crotonaldehyde, Cyclohexene, Benzylbenzoate, and Benzyl diethyl
malonate.
10. Rearrangement reactions: Mechanism of rearrangement reaction involving carbocation,
nitriene and oxonium ion intermediate.Beckmann, Bayer-Villiger, Pinacol-pincolone,
Curtis, Favorski, Claisen rearrangement.
11. Spectroscopic methods in structure determination of organic compounds: Different units of
measurement of wavelength frequency, different regions of electromagnetic radiations.
Interaction of radiation with matter, excitation of molecules with different energy levels,
such as rotational, vibrational and electronic level, types of spectroscopy and advantages
of spectroscopic methods.
12. Natural Products: Terpenoids and alkaloids
Biochemistry
1. Amino acids and proteins: Introduction, biological functions, classification-based on
structure, function and composition. Structural organization of proteins- primary,
secondary, tertiary and quarternary structures (general overview). Factors that stabilize
protein structure. Denaturation of Proteins.
2. Carbohydrates: Introduction of carbohydrates, Introduction and biological significance
of proteoglycans, Glycoproteins, Glycolipids, Analysis of carbohydrates.
3. Lipids: Introduction, Biological significance, Classification-Simple, compound,
steroids and derived lipids. Structure of saturated and unsaturated fatty acids, structure
of phospholipids (Phosphatidic acid, Lecithin, Cephalin, Lipositol), structure of
Sphingomyelin and Cholesterol. Amphipathic lipids and their behavior in water.
Saponification number, Acid number, Iodine number and their significance. Rancidity
of lipids. Structural Lipids in membrane glycerophospholipids, Sulphalipids,
Galactolipids, glycosphingolipids
4. Hormones: Definition, classification based on biochemical nature, location and
mechanism of action.
5. Enzymes: Classification- Six major classes of enzymes, Conjugated enzymesApoenzyme,
Holo-enzyme, prosthetic group (coenzymes and cofactors). Features of
active site. Enzyme specificity, Factors affecting enzyme activity- substrate
concentration, pH, temperature, and enzyme concentration, product concentration. MM
equation, LB equation and significance of Km. Enzyme inhibition-competitive, noncompetitive
and uncompetitive with suitable examples. Allosteric enzymes and clinical
significance of Isoenzymes.
6. Vitamins and Coenzymes: Classification- Fat soluble and water soluble vitamins
(source, biological functions and deficiency disorders), coenzyme forms of vitamin B
complex.
7. Cell Biochemistry: Introduction to Cell, Unicellular and Multicellular organisms,
Distinguishing features of Prokaryotic and Eukaryotic cell. Structure and function of
Cell membrane, Mitochondria, Endoplasmic reticulum, Golgi complex, Lysosomes,
Peroxisomes, Plant cell wall and Chloroplast. Concepts of Biomolecules and types of
bonds in biomolecules.
8. Biochemical techniques: Principle, working and applications of dialysis, Paper
chromatography, TLC, Column chromatography- Gel filtration, Ion exchange, Affinity
Chromatography. Electrophoresis- Paper and Gel (Agarose, Native and SDS- PAGE).

For more details you may contact to the Pune university the contact details are given below


Contact details :
Pune university
Address: Ganeshkhind, Pune, Maharashtra 411007
Phone: 020 2569 6064