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    Syllabus for M.Sc. I Chemistry , University of Pune


    M.Sc. Chemistry Part- I

    The following will be the structure for Revised Syllabus from June 2008 for

    semester I and Semester II

    Semester – I
    CH – 110 Physical Chemistry – I
    CH – 130 Inorganic Chemistry – I
    CH – 150 Organic reaction mechanism and stereochemistry.
    CH – 107 Physical Chemistry practical ( Departmental Course)
    CH – 127 Inorganic Chemistry Practical ( Departmental Course)

    Semester – II
    CH – 210 Physical Chemistry II
    CH – 230 Inorganic Chemistry II
    CH – 250 Synthetic organic Chemistry and Spectroscopy.
    CH – 290 General Chemistry ( Departmental Course) elective)
    CH – 247 Organic Chemistry practical ( Departmental Course)

    Structure of
    M.Sc. Part – II :- ORGANIC CHEMISTRY
    SEMESTER : - III –
    1. CH – 350 Organic Reaction Mechanism
    2. CH – 351 Spectroscopic Methods in structure Determination
    3. CH – 352 A Organic Stereochemistry.
    B. Green Chemistry, Microwave reactions.
    4. CH – 353 Pericyclic Reactions, Free radicals and Photo Chemistry.

    SEMESTER :- IV –
    1. CH – 450 Chemistry Of Natural Products.
    2. CH – 451 Synthetic Methods in Organic Chemistry
    3. CH – 452 Heterocyclic Chemistry; Chiron Approach; Medicinal
    Chemistry;
    Vitamins, Hormones Antibiotics etc.
    4. CH – 453 Organic Molecules related to Nano matelial.
    Practical Courses:-
    1. CH – 347 Ternary Mixture Separation
    2. CH – 447 Two Stage Preparations.
    3. CH – 448 Project / Preparations
    Important Notes
    1. Each theory course prescribed for M. Sc. should be covered in 4 periods, each
    of 60 minutes duration per week per course including lectures, tutorials,
    seminars etc.
    2. Each practical course will require 6 hours of laboratory work per week and the
    course will be extended over two semesters and will be examined at the end of
    the year.
    3. There should not be more than 10 students in a batch for M. Sc. practical
    course.
    4. For theory course the question paper should include at least 20 % weight age
    for problem solving. Problem solving would include numerical, short answer,
    long answer questions to test understanding of the subject.
    5. Of the 60 lectures in each course about 10 lectures will include tutorials,
    student seminars and class tests.
    6. Two interactive sessions per course per semester must be conducted by
    concerned teachers.

    PHYSICAL CHEMISTRY CH – 110
    SECTION – I
    TEHRMODYNAMICS
    1) Recapitulation :-
    Heat, Work, & Conservation of energy – The basic concepts, the first law,
    infinitesimal changes, mechanical work, work of compression & expansion, free
    expansion, Expansion against constant pressure, reversible expansion, Heat :- heat
    capacity, enthalpy.
    State functions & differentials – state functions, Exact & Inexact differential,
    changes in internal energy, temperature dependence of the internal energy,
    Temperature dependence of the enthalpy. Work of adiabatic expansion-
    Irreversible adiabatic expansion, reversible adiabatic expansion.
    Ref 1 Page No. 38 to 74 Periods – 02
    2) The Second law of Thermodynamics
    Measuring the dispersal the entropy, The second law, the definition of entropy,
    the entropy changes in the system, natural events. Entropy changes in the universe
    – The enthalpy change when a system is heated, Entropy changes in surroundings,
    The entropy of phase transition, The entropy of irreversible changes.
    Concentrating on the system – The Helmoltz & Gibbs function, some remarks on
    the Helmholtz function, Maximum work, some remarks to Gibbs function 2.4
    Evaluating the entropy & Gibbs function, The Third law of Thermodynamics,
    Third law entropies standard molar Gibbs function.
    Ref 1 Page No. 96 to 117. Periods – 05
    3) Combining First & Second Law –
    One way of developing the fundamental equations Properties of Gibbs
    function, The temperature dependence of the Gibbs functions, The pressure
    dependence of the Gibbs functions, The Chemical potential of a perfect gas, The
    open system & changes of composition.
    Ref 1 Page No. – 121 – 127, 131. Periods – 03
    4) Changes of State :
    Physical Transformation of pure materials. The stability of phases, Phase
    equilibrium & phase diagrams, The solid – liquid boundary, The liquid-vapour
    boundary, The solid- vapour boundary, The solid-liquid-vapour equilibrium.
    Ref. 1 Pages – 137 to 143. Periods – 03
    5) Changes of State
    Physical transformation of simple mixtures, Partial molar quantities Partial
    molar volume, Partial molar Gibbs function, The thermodynamics of mixing – the
    Gibbs function of mixing after thermodynamics mixing functions, The chemical
    potential of liquid-liquid mixture, colligate properties- The common features, the
    elevation of boiling point, The depression of freezing point, solubility, osmosis,
    Mixtures of volatile liquid – vapour pressure diagram – The representation of
    distillation, azeotropes, immiscible liquids.
    6) Changes of States –
    Chemical reactions, Which way is downhill – The Gibbs function minimum,
    Exergonic & endergonic reaction, perfect gas equilibria, A recipe for equilibrium
    constants real gas.
    Ref 1 Page-161 to 181, Ref. Page No. 212 to 217, Periods – 07
    QUANTUM CHEMISTRY
    Historical development of quantum theory principal of quantum mechanics,
    wave particle duality, uncertainty principles, Schrödinger equation, operators simple
    system – free particle, Particle in a box, Two dimensional Three dimensional box,
    Hydrogen like atoms ( no derivation ) atomic orbital. Periods – 10
    Reference Books -
    1. Physical Chemistry - P.W. Atkin, ELBS fourth edition.
    2. Physical Chemistry – R.A. Alberty, R.I. Bilby, Johy Wiley – 1995
    3. Physical Chemistry – G.M. Barrow, Tata Mc – Graw Hill – 1988
    4. Quantum Chemistry, - I . Levine, Fifth edition, Prentice Hall- 1999
    5. Physical Chemistry – Thomas Engel, Philip Reid.

    Section – II
    1. CHEMICAL KINETICS
    1. Recapitulation:-
    Reaction rate, Rate law & rate constants, The determination of rate law, first
    order reactions, second order reactions, Half life.
    Ref 1 Page – 689 to 697. Periods - 02
    2. According for rate laws:-
    Simple reactions, The temperature dependence of reaction rates, Reaction
    approaching equilibrium consecutive reactions, The steady state approximations,
    Pre-equilibira, Unimolecular reactions, Enzyme catalysis – Michaelis Menton
    mechanism, Lineweaver and Eadie plots, The kinetics of complex reaction, Chain
    reactions, the structure of chain reactions Explosions, - Fast reactions, flash
    photolysis, Flow technique, relaxation methods,
    Ref. 1 Page -698 to 708, Ref 1 Page – 714 to 716 Ref1 Page – 720 Ref. 1
    Page 729 to 732 Period – 12
    3. Molecular reaction dynamics:-
    Collision theory basic calculation, the steric requirement, Diffusion controlled
    reactions- Classes of reactions, diffusion & reaction, the details of diffusion,
    Activated complex. The reaction co – ordinate & transition state, the formulation
    & decay of the activated complex, How to use the Eyring equation.
    Thermodynamic aspect, reaction between ions, Dynamics of molecular collisions,
    Ref 1 Page – 737 to 758. Period - 06
    2. STATISTICAL THERMODYNAMICS
    Thermodynamic probability of a system, the moat probable distribution, the
    partition function, systems of independent particles, the energy of a system, the
    separation of partition function, The partition function for translation, The
    thermodynamic functions for translation, monochromic gases, Thermodynamic
    function for rotation, vibration, & Electronic excitation, Rotation, the electronic
    portion function, Results of statistical Calculation, statistical calculation of
    equilibrium constant, entropy & probability, Bose-Einstein & Fermi Dirac Statistics.
    Ref . 2 Page – 751 to 772. Periods - 10
    Ref 1 Physical chemistry – P.W. Atkins, ELBS Fourth edition.
    Ref 2 Principles of Physical chemistry – S.H. Maron & C.F. Pruton fourth edition
    Ref. 3 Chemicals Kinetics, K.J. Laidler ( Tata Mc. Graw Hill) 1998
    Ref . 4 Physical Chemistry, T. Engle and P. Reid, (Pearson Education) 2006
    Ref. 5 Basic Chemical Thermodynamics, E. Brian Smith (ELBS) 1990
    Ref. 6 Statistical Thermodynamics, L.K. Nash.
    Ref.7 Physical Chemistry molecular approach, D.Mcquarie and J. Simom(Viva) 2000.
    CH – 210 PHYSICAL CHEMISTRY
    Section I : MOLECULAR SPECROSCOPE ( 30 Lectures)
    1. Recapitulation : Width and intensity of spectral transitions, Forier transform,
    microwave spectroscopy, rotation spectra of di – and poly- atomic molecules,
    Stark effect. (5)
    2. Infra red spectroscopy : Harmonic and an harmonic oscillator, vibrational spectra
    of di – and poly- atomic molecules, coarse and fine structure, Nuclear spin effect,
    application, (7)
    3. Raman Spectroscopy: Introduction, Rotational Raman spectra, Vibrational Raman
    Spectra, polarization of light and Raman effect, structure elucidation from
    combined Raman and IR spectroscopy, applications in structure elucidation. (6)
    4. Electronic spectroscopy of molecules: Born – Oppenheimer approximation,
    electronic spectra of diatomic molecules, vibrational coarse structure, rotational
    fine structure dissociation energy and dissociation products, electronic structure of
    diatomic molecules, molecular photoelectron spectroscopy, application. (8)
    5. ESR and Mossbaur spectroscopy applications. (2)
    6. Principles of NMR – Chemical applications of PMR in structure elucidation. (2)
    References:-
    i) Fundamentals of molecular spectroscopy : C.N. Banewell and E.Mc. Cash
    ( Fourth edition).

    SECTION II : NUCLEAR & RADIATION CHEMISTRY (30)
    1) Radio Chemistry : recapitulation – type of radioactive decay, Decay Kinetics,
    Detection & measurement of radiation ( G.M. & Scintillation counter) (03)
    2) Elements of radiation chemistry – Radiation chemistry, interaction of
    radiation with miller, passage of nucleous through matter, interaction of
    radiation with matter, Units. for measuring radiation absorption, Radiation
    dosimetry, Radiolsis of water, free radiation in water Radiolsis, Radiolysis of
    some aqueous solution. (08)
    3) Nuclear Reactor :-
    The fission energy, The Natural uranium reactor, the four factor
    formula- The reproduction factor K, the classification of reactor. Reactor
    power, Critical size of thermal reactor, excess reactivity & control, the Breeder
    reactor, The Indians nuclear energy programme, Reprocessing of spent fuel :
    Recovery of Uranium & Plutonium, Nuclear waste management, Natural
    nuclear reactor. (08)
    4) Isotopes for nuclear reactors.
    Isotope separation, separation of selected isotopes, Plutonium. (4)
    5) Applications of radioactivity :-
    Typical reaction involved in preparation of radioisotopes:
    3H, 14C, 22Na, 32P, 35S, and 137IGeneral principles of using radioisotopes.
    - Physical constants – Diffusion coefficients, surface area, solubility.
    - Analytical applications- neutron activation analysis, dilution analysis,
    radiometric titration.
    - Industrial applications – ratiation guaging, friction and wear out,
    gamma radiography.
    Reference Books.
    1. Elements of Nuclear chemistry – H.J. Arnikar, fourth edition wiley Estern Ltd.
    2. Source book of atomic energy – S. Glasstanc, D. Van Norton company.
    3. Chemical applications of radioisotopes – H.J. M. Brown Buffer & Jammer
    Ltd.
    CH – 107 :- PHYSICAL CHEMISTRY PRACTICALS :
    A) Conductometry:
    i) Hydrolysis of NH4Cl or CH3COONa or aniline. hydrochloride.
    ii) Determination of λ0 or λα and dissociation constant of acetic acid.
    iii) Hydrolysis of ethylacetate by NaoH.
    iv) Determination of ..G, ..H, and .. S of Silver Benzoate by conductometry.
    B) Poetentiomerty:-
    1. Stability Constant of a complex ion.
    2. Solubility of a sparingly soluble salt.
    3. To determine the ionic product of H2O
    4. Estimation of halide in mixure.
    C) pH metry:-
    1. Determination of the acid and base dissociation constant of an amino acid and
    hence the isoelectric point of the acid.
    D) Polarography
    1. Determination of half wave potential E 1/2 and unknown concentration of an
    ion.
    2. Amperometric titration of Pb( NO3)2 with K2Cr2 O7
    E) Colorimetric :-
    1. Analysis of a binary mixture.
    2. Copper EDTA photometric titration.
    F) Radioactivity:-
    1. Estimation of Mn in tea leaves by NAA
    2. Half – life of a radioactive nuclide and Counting errors.
    3. Determination of Emax of beta radiation and absorption coefficients in Al.
    G) Chemical Kinetics:
    1. Kinetic decomposition of diacetone alcohol by dilatometry.
    2. Determination of an order of a reaction.
    3. Bronsted primary salt effect.
    H) Non- Instrumental :-
    1) Freundlich and Longmuir isotherms for adsorption of acetic acid on active
    charcoal
    2) Statistical treatment of experiemntal data
    3) Molecular weight by steam distillation.
    4) Glycerol radius by viscosity.
    5) Partial Molar Volume ( Polynometry) Determination of the densities of a
    series of soltions and to calculate the molar volumes of the components. Each
    candidate should perform a minimum of 18 experiments with at least one
    experiment form each techniques.
    I) Surface area analysis by BET method e.g. industrial pigment
    References:-
    1. Practical physical chemistry, A. Findary, T.A. kitchner ( Longmans, Green
    and Co.)
    2. Experiments in Physical Chemistry, J.M. Wilson, K.J. Newcombe, A.r.
    Denko. R.M.W. richett ( Pergamon Press)
    3. Senior Practical Physical Chemistry, B.D. Khosla and V.S. Garg (R. Chand
    and Co., Delhi.)


    (OLD) CH – 130 : INORGANIC CHEMISTRY – I
    ( New) CH – 130 Symmetry, Stereo & Main group chemistry (60 L)
    A. Symmetry & Stereochemistry (30L)
    1 Definitions and theorems of group theory, subgroups, Classes (2L)
    2
    Molecular symmetry and symmetry groups – symmetry elements
    and operations. Symmetry planes, reflections, inversion centre,
    proper/ improper axes of rotation, products of symmetry
    operations, equivalent symmetry elements and atoms, symmetry
    elements and optical isomerism, symmetry point groups, classes
    of symmetry operations, classification of molecular point groups.
    (2L)
    3
    Representations of groups
    Great orthogonality theorem, character tables, properties of
    characters of representations. ( No mathematical part.)
    (10L)
    4
    Group theory and quantum mechanics,. Wave function as basis for
    irreducible representations.
    (2L)
    5
    Symmetry Adapted Linear Combinations (SALC) – Projection
    operators and their use of construct SALC
    (4L)
    6
    Molecular Orbital Theory
    Transformation properties of atomic orbital, MO’s for Sigma
    bonding ABn molecules, tetrahedral AB4 case.
    (2L)
    7
    Crystallographic Symmetry.
    Unit cell, screw axis, glide plane on unit cell, crystal lattice, space
    lattice, stereographic projectors. Examples on crystallographic
    planes, cubic planes, Miller indices, Bravais lattices.
    (6L)
    B. Chemistry of Main group Elements (30 L)
    1
    Hydrogen & its compounds:
    Hydrides Classification, e deficient, e precise & e rich hydrides
    PH3,SbH3, AsH3 , Selenides, Tellurides.
    (3L)
    2
    Alkali & alkaline earth metals
    Solutions in non-aqueous Media.
    Application of crown ethers in extraction of alkali & alkaline
    earth metals.
    (2L)
    3
    Organometallic compounds of Li, Mg, Be, Ca, Na
    Synthesis , properties, uses & structures.
    ( 3 L)
    4
    Boron group
    Boron Hydrides, preparation, structure & bonding with reference
    to LUMO, HOMO, interconversion of lower & higher borances,
    Metalloboranes, Carboranes.
    (4L)
    5
    Carbon group
    Allotropes of Carbon, C60 and compounds (fullerenes),
    Intercalation compounds of Graphite, Carbon nanotubes,
    synthesis, Properties, structure- single walled, Multiwalled,
    applications, classification of organomentallic compounds.
    Organometallic compounds of B, Si, Sn, Pb, Ga,As, Sb, Bi.
    Structures, Synthesis, Reactions.
    (8L)
    6
    Nitrogen group
    Nitrogen activation, Boron nitride, Oxidation states of nitrogen &
    their interconversion PN & SN compounds
    Nos, & their redox chemistry.
    ( 3L)
    7
    Oxygen group
    Metal selenides & tellurides, oxyacids & oxoanions of S & N.
    Ring, Cage and Cluster compounds of P- block elements.
    Silicates, including Zeolites
    (2L)
    8
    Halogen group
    Interhalogens, Pseudohalogen, synthesis, properties &
    applications, structure, oxyacids & oxoanions of Hallogens
    Bonding.
    (3L)
    9
    Noble gases
    Synthesis, properties, uses, structure & bonding with respect to
    VSEPR.
    (2L)
    Text Books:
    1. Chemical application and group Theory: F.A. Cotton, 3rd edition ( 1999)
    2. Advanced Inorganic Chemistry :F.A. Cotton, G. Wilkinson, C.A. Murillo,
    M.Bochmann 6th Edn. (2003)
    Reference Books:
    1. Symmetry in Chemistry: H. Jaffe’ and M. Orchin (2002)
    2. Group theory and its chemical application: P.K. Bhattacharya, 2nd edn. (1989)
    (Himalaya Publication)
    3. Inorganic Chemistry: Shriver and Atkins, 4th edn. (2003) Oxford.
    CH – 127 : INORGANIC CHEMISTRY PRACTICALS.
    1. Ore Analysis: At least two of the following:-
    a. Determination of Silica and Manganese in pyrolusite
    b. Determination of Copper and iron from chalcopyrite.
    c. Determination of iron from hematite.
    2. Alloy Analysis ( At least two of the following)
    a. Determination of tin & lead from solder.
    b. Determination of iron & chromium from mild steel.
    c. Determination of copper and nickel from cupronickel.
    3. Inorganic Synthesis and Purity determination (any five)
    a. Cis/trans potassium di-aquo di-oxalato chromate (III)
    b. Chloro penta-ammino cobalt (III) chloride
    c. Nitro penta-ammino cobalt ( III) chloride
    d. Nitrito penta-amino cobalt ( III) Chloride.
    e. Tris, 2-4 pentanedionato cobalt ( III)trihydrate
    f. Potassium tri-oxalato aluminate
    g. Reinecke’s salt.
    4. Nickel complexes; Preparation of [Ni(en)3] S2O3, [Ni(H2O)6] Cl2, [Ni(NH3)6]
    Cl2 and studying their absorption spectra.
    5. Ion – exchange chromatography; Separation & estimation of (Zn+2/ Cd+2) &
    (Zn+2 / Mg+2) in mixtures using Amberlite IRA 400 anion exchanger.
    6. Instrumental methods of analysis.
    a. Colorimetry:
    i. Simultaneous determination of Cr. & Mn.
    ii. Determination of Keq of M – L systems such as
    Fe (III) – Salicylic acid
    Fe(III) – Sulphosalicylic acid
    Fe(III) – β – resorcilic acid by Job’s &Mole ratio method.
    iii. Determination of iron by solvent extraction techniques in a
    mixture of Fe+3 +AL+3 & Fe+3 + Ni+3 using 8 - hydroxyquinoline
    reagent.
    b. Conductometry.
    Verification of Debye Huckle theory of ionic conductance for
    strong electrolytes KCl, BaCl2, K2SO4, K3[Fe(CN)6]
    c. Table work; ( any one)
    i. Analysis of Electronic Spectra of transition metal complexes at
    least for one system [dn (Oh) or (Td)] and calculation of Crystal
    Field parameters, interelectronic repulsion parameter and
    bonding parameter.
    ii. Data analysis, error analysis, lest squares method Plot of Born
    Maeyer to determine for 1 : 1 type molecule to determine inter
    nuclear separation. Characterization of metal ligand bonding
    using IR spectroscopy.
    7. Synthesis and Characterisation of nano materials : Quantur dots (cds)
    Reference Books:
    1) Text book of Quantitative Analysis, A.I. Vogel 4th edn (1992)
    2) Electronic Spectroscopy by A.B. P. Lever.
    3) Inorganic Synthesis (Vol. Series)
    4) Practical Manual made By Department of Chemistry, University of Pune.
    (OLD) CH – 230: INORGANIC CHEMISTRY – II
    (New) CH – 230 : Coordination & Bioinorganic chemistry) (60L)
    A. Coordination Chemistry. (30L)
    1 Concept & Scope of Ligand Fields (2L)
    2
    Energy levels of transition metal ions, free ion terms, term wave
    functions, spin-orbits coupling.
    (6L)
    3
    Effect of ligand field on energy levels of transition metal ions,
    weak cubic ligand field effect on Russell- Saunders terms, strong
    field effect, correlation diagrams, Tanabe- Sugano Diagrams,
    Spin-Pairing energies.
    (8L)
    4
    Electronic spectra of complexes- band intensities, band energies,
    band width & shapes, spectra of 1st , 2nd & 3rd row ions and rare
    earth ion complexes, spectrochemical & nephlauxetic series,
    charge transfer & luminescence, spectra, calculations of Dq, B, β
    parameters.
    (10L)
    5
    Magnetic properteis of complexes-paramagnetism 1st & 2nd
    Ordered Zeeman effect, quenching of orbital angular momentum
    by Ligand fields, Magnetic properties of A, E & T ground terms
    in complexes, spin free spin paired equilibria
    (4L)
    B. Bioionrganic chemistry (30L)
    6 Overviews of Bioniorganic Chemistry (2L)
    7
    Principles of Coordination Chemistry related to Bioionorganic –
    Protein, Nucleic acids and other metal binding biomolecules.
    (9L)
    8 Choice, uptake and assembly of metal containing units in Biology (7L)
    9 Control and utilization of metal ion concentration in cells. (8L)
    10
    Binging of metal ions and complexes to bimolecular active
    centers.
    (4L)
    Text Books:
    1. Ligand field theory & its applications: B.N. Figgis & M.A. Hitachman (2000)
    Wiely VCH Publ.
    2. Principles of Bioionorganic Chemistry: S.J. Lippard & J.M. Berg (1994),
    University Science books, Mill Valley, California.
    Reference Books:
    1. Inorganic Chemistry: Shriver & Atkins (1990) Oxford.
    2. Inorganic Electronic spectroscopy: A.B.P. Level, 2nd edn. (1984)
    Elsevier Science Publishers New York.
    3. Biological Chemistry of the Elements: R.J.P. Williams & F.R. Desalvia,
    Oxford University Press – (1991)
    4. Bioinorganic Chemistry : Inorganic elements in the Chemistry of life : An
    introduction & guide: W. Kaim, B. Schwederski, VCH, 1991 (1991).

    CH- 290 : GENERAL CHEMISTRY
    DEPARTMENTAL COURSE
    ANY TWO PARTS
    PART A
    Modern Separation Methods & Hyphenated Techniques: (30L)
    1
    Gas Chromatography: Gas chromatography theory and
    Instrumentation, Column types, Solid/ Liquid Stationary Phases,
    Column Switching techniques, Basic and Specialized detectors,
    elemental detection, chiral separations, pyrolysis gas
    chromatography, High temperature techniques. Application
    (Clinical, petrochemical etc.) and problems.
    (8L)
    2
    High performance Liquid Chromatography methods: HPLC theory
    and instrumentation, Adsorption chromatography, Liquid-Liquid
    partition techniques, Microbore and capillary chromatography,
    Affinity techniques, Size exclusion, ion pait separtions, Chiral and
    Isotope separations, Applications and problems.
    (8L)
    3 Ion Chromatography (2L)
    4
    Electrophoresis : Separation by Adsorption- Affinity techniques,
    Affinity elution from Ion exchangers and other Adsorbents, Pseudo
    affinity adsorbents polycrylamide gel electrophorsis, Isoelectic
    focussing Isotachophoresis, Two dimensional gel electrophoreisis,
    Capillary electrophoresis in rotation- stabilized media,
    Electrophoresis in stabilized salts. Applications in Nuclei acids,
    Clinical and capillary zone electrophoresis of carbohydrates.
    (6L)
    5
    Hyphenated Techniques
    Mass spectrometry principle, Instrumentation, Ionization methods –
    EL, CI, FAB, arc & spark, photoionization, thermal ionization, Fl*&
    FD, laser induced, Photoelectic ionization, SIMS, Mass analyzers –
    Magnetic, Double foucusing, Time of flight, Quadrupolar,Ion
    cyclotron resonance analyzer. Coupled techniques, GC FTIR, GCMS
    ( Use of stable isotopes) HPLC-MS.
    (6L)
    Text Books:
    1. Fundamentals of Analytical Chemistry”, D.A. Skoog, D.M. West, F.J. Holler,
    S.R.Crouch 8th, edn.
    2. Instrumental Methods of Analysis H.H. Willard, L.L. Merritt Jr., J.A. Dean, F.A.
    Settle (CBS Publisher) 7the edn.
    Reference Books
    1. Practical Aspects of Gas chromatography/ Mass spectrometry.
    G.M.Message, John wiley & sons, New York, (1984).
    2. HPLC: Analytical Chemistry by Open Learning John Wiley & Sons, New
    York, (1991).
    3. Protein Purification: Principles & Practice.
    Spring International, 3rd Edition, New Delhi, StudentsEdn. (1994).
    Part B
    Bimolecular: (30L)
    1
    Cell Structure and function
    Prokaryotes & Eukaryotes membrance & cell structure, subcellular
    components; nucleus, Mitochondria, Endoplasmic reticulum, Golgi
    apparatus, Lysosomes, peroxisomes.
    (4L)
    2 Water (2L)
    3
    Proteins
    Introduction, Amino acids, Classification of amino acids, physicochemical
    properties, reactions with different reagents, Essential &
    nonessential amino acids. Peptides, end terminal analysis, Primary
    secondary, tertiary and quaternay structures of Priteins Helix, sheets,
    super secondary structure, triple helix structures,globular and fibrous
    proteins.
    (8L)
    4
    Carbohydrates: Introduction, Classification, structures, stereo
    chemical properties and functions. Derivatives of monosaccarides
    and their functions.
    (5L)
    5
    Lipids : Classification, functions. Membrane structure, its
    organization & functions.
    (4L)
    6
    Nucleic acids: DNA & RNA types, structure and function. Super
    coiling of DNA Central dogma, physicochemical properties.
    (3L)
    7 Vitamins: Structure, biochemical functions& deficiency disorders. (4L)
    Text Book:
    1. Organic Chemistry (5th Edn.) Robert. T.Morrison & N. Boyd. Hill edn.
    2. Lehninger’s Principles of Biochemistry, (4th edn.), David L. Nelson, Michael
    M.Cox.
    References:
    1. Biochemistry (5th edn.) Lubert Stryer.
    2. Biochemistry and Physiology of the cell (2nd edn) Edwards and Hassall.

    Part – C
    Concepts of Analytical Chemistry:
    1. Methods of Analytical Chemistry- Introduction, general analytical process,
    methods of analytical determination. (4L)
    2. Error in chemical analysis – Errors & precision, classficiation of errors,
    determinate errors, determination of accuracy of quantitative analytical
    methods, accuracy sought. (6L)
    3. Accuarcy & precision – The test of statistics precision, averages, study of an
    analytical procedure, sampling errors, presentation of results. (6L)
    4. Principles & Methods of sampilng- Introduction, theory of sampling, pit falls
    is sampling, technique of sampling gases, liquids and solids, transmission
    and storage of samples, sources specific sampling information. (8L)
    5. Use of Computer programs:
    Linear regrression, XY Plots, numerical integration & differentiation,
    operating with packages such as PCMODEL, WINMOPAC Word
    processing, Use of MSWORD, Power point & Excel in chemistry, Use of
    Internet. (6L)
    Text Books:
    1. Analytical Chemistry :G.D. Christian, Wiley, 6th edn.
    Reference Books:
    1. Computational Chemistry , G.Grant and W.Richards, Oxford University press.
    2. Computer Programming in Fortran 77 and Fortran 90,, V. Rajaraman, Prentice
    Hall india.
    Part D : Chemical Mathematics
    Part E – Industrial Methods of Analysis.
    Part F Computers for chemists.
    Note : Syllabus for above said Part- D, Part- E & Part – F is same as the old syllabus.
    CH-150 : ORGANIC CHEMISTRY
    (Reaction mechanism and stereochemistry)
    1. Nature of Bonding in Organic Molecules. (12 lectures)
    A. Delocalized chemical bonding – Conjugation, cross conjugation, resonance,
    hyper conjugation, tautomerism, inductive Resonance effects.
    B. Acidity and Basicity.
    C. Introduction to aromaticity in Benzenoid and non – Benzenoid compounds,
    alternant and non-alternant hydrocarbon, Huckel Rule. Bonds weaker than
    covalent – addition compounds, Crwon ether complexes and Cryptands
    inclusion compounds, cyclodextrins, Catenanes, rotaxanes and bonding in
    Fullerences.
    Ref. 5 (Page No. 26 to 74 and 260 to 272.)
    2. Stereochemistry (12 Lectures)
    Stereo chemical Principlse – Enantiometric relationships, diastereomeric
    relationships, R and S, E and Z nomenclature, dynamic stereochemistry,
    parochiral relationship, stereo-specific and stereo selective reactions. Introduction
    of optical activity in the absence of chiral carbon (biphenyls, spiranes, allenes and
    helical structures).
    Ref. 5 ( Page No. 94 to 115 and 125 to 130).
    3. Aliphatic Nucleophilic Substitution (12 Lectures)
    The SN2, SN1, mixed SN1 and SN2 and SET mechanism. The neighboring
    group mechanism, The Neighbouring group participation by π & σ bonds,
    anchimeric assistance, classical and non classical carbocations, phenonium ions,
    norbornyl syste, carbocation rearrangements in neighboring group participation.
    The SNi mechanism. Nucleophile Substitution at an allylic, aliphatic trigonal and
    vinylic carbon. Reactivity effects of structure, attacking Nucleophile, leaving
    group and reaction Medium Phase transfer catalyst, ambident nuclephile and
    regioselectivity.
    Ref 5 ( Page No. 293 to 369)
    4. Addition to Carbon – Carbon Multiple bonds (6 lectures)
    Mechanistic and Stereo chemical aspects of addition reactions involving
    electrophiles,nucleophiles and Free radicals, Regio and Chemo selectivity,
    Orientation and reactivity, Michael reaction.
    Ref. 1 (Page no. 167 – 210.)
    5. Aromatic Electrophilic Substitution ( 8 Lectures)
    The arenium ion mechanism, orientation and reactivity, energy profile
    diagram, The ortho/ para ratio ipso attack, orientation in other ring system,s
    Naphthalene, Anthracene, Six and five membered heterocycles, Diazonium
    coupling Vilsmeier reaction, Gattermann – Koch reaction, etc.
    Ref. 5 (page no. 501 to 517 and 520 to 545)
    6. Aromatice Nucleophilic Substitution ( 4 Lectures)
    the SNAr, SN1 Benzyne & SNR1, Mechanisms, Reactivity effect of substrate
    structure, leaving group and attacking nucleophile.
    Ref . 5 ( Page No. 641 to 653)
    7. Elimination reactions ( 6 Lectures) :-
    E2, E1, E1cb Mechanisms, Orientation, stereochemistry in elimination, reactivity
    effect of structre attacking and leaving groups, competition between substitution
    & elimination , syn eliminations.
    Ref. 5 (relevant pages)
    CH – 250 : SYNTHETIC ORGANIC CHEMISTRY AND SPECTROSCOPY
    1. Oxidation and Reduction ( 12 Lectures)
    CrO3 (Jones reagent) PDC, PCC, KMnO4, MnO2 , Swern, SeO2, Pb ( OAc)4,
    Pd/C, OsO4, mCPBA, O3, NalO4, HIO4 R3 SiH, Bu3SnH, Boranes &
    Hydroboration reactions, MVP, H2/ catalyst, Wilkinson’s catalyst, NaCNBH3,
    NH2NH2, DIBAL, etc.
    Ref. 1, 2, 10 ( relevant pages)
    2. Rearrangements ( 10 Lectures)
    a. Reactive intermediate, Carbocations, carbanions,carbenes, nitrenes
    b. Beckmann, Hofmann, Curtius, Schmidt, Wolf, Lossen, Baeyer – Villiger,
    Sommelet, Favorskii, Pinacole – Pinacolone, Benzil – Benzillic acid,
    Claisen and Cope Rearrangements, Fries Migration.
    Ref 3 ( page no. 618 to 660)
    3. Phosphorous, Nitrogen and Sulphur Ylids and stereochemistry of compounds
    containing Phosphrous, Sulfur and Nitrogen ( 4 Lectures)
    Ref. 1, 4 ( relevant pages)
    4. Addition to Carbon – Hetero Multiple bonds ( 6 Lectures)
    Addition of Grignard Reagent, Organo Zinc, Organo Copper, and Organo
    lithium reagents to Carbonyl and unsaturated Carbonyl compounds.
    Ref. 1 ( Page No. 376 -394) and (Page No. 615 to 664)
    Ref. 5 ( page no. 920 – 936)
    5. Conformation of acyclic molecules and shape of six membered rings
    (6 Lectures)
    Ref. 11 ( Page No. 124 to 139 and 204 to 215)
    6. Spectroscopy ( 22 Lectures)
    a. U.V. : Electronic transitions, Chromophores, Auxochromes,
    Bathochromic and hypsochromic shifts, Solvent effects, Wood ward –
    Fieser Rules for dienes. enones and aromatic compounds Applications of
    U.V., instrumentation of recording of spectra.
    Ref 6, 7 (relevant pages)
    b. I.R.: Vibrational Transitions, Important group frequencies, Factors
    affecting I.R. group frequency, Applications of I.R. Instrumentation and
    recording of spectra.
    REf. 8 (relevant pages)
    c. NMR. : Elementary ideas of NMR Integration, Chemical shifts. Factors
    affecting, Chemical shifts, Coupling ( First order, analysis),
    Instrumentation & recording of spectra.
    Ref. 6, 9, 13 (relevant pages)
    d. Problems in U.V., I.R. and N.M.R.
    Ref. 13
    References:
    1. Carey and Sundberg. (Ed. III) , Part B – Adv. Organic Chemistry.
    2. H.O. House , Synthetic Organic Chemistry.
    3. Gould E.S., Mechanis and Structure in Organic Chemistry.
    4. Norman R.O.C. Organic Chemistry.
    5. J. March,(Ed IV), AdvOrganic Chemistry.
    6. Silversteine and Basser, Spectrometric Identification of Organic Compounds.
    7. Kalsi, Organic Spectroscopy.
    8. J. Bellamy, Infrared spectra of Complex molecules.
    9. I Fleming, Organic Spectroscopy.
    10. J. Clayden, N.Greeves et. al Organic Chemistry
    11. Eliel, Stereochemistry.
    12. D. Nashipuri, Stereochemistry of Organic Compounds
    13. Pavia Spectroscopy of Organic Compounds
    14. Vogel Practical Organic Chemistry.
    CH – 247 : ORGANIC CHEMISTRY PRACTICALS
    1. Techniques:
    Crystallization, fractional crystallization, fractional distillation, vacuum
    distillation, sublimation, steam distillation, column chromatography, thin layer
    chromatography ( purity would be checked by m.p. and mixed m.p.)
    2. Preparation of derivatives.
    Oxime, 2,4 – DNP, acetyl, benzoyl, semicarbazide and aryloxyacetic acid,
    Anilide, Amide.
    3. Preparations: Single Stage / Double stage.
    Single Stage ( Any Four)
    i) Cyclohexanone to adipic acid.
    ii) Benzaldehyde to dibenzylidene acetone
    iii) Benzaldehyde to cinnamic acid
    iv) P – aminobenzoic acid to p-chlorobenzoic acid
    v) 4 – Chlorobenzalehyde to 4 – Chlorobenzoic acid + -chlorobenzyl alcohol
    (Canninzzaro reaction)
    vi) Benzene to β – benzoyl propionic acid (Friedel Craft reaction)
    vii) N, N, Dimethyaniline to 4 – Formyl – N, N – Dimethylaniline.
    viii) Benzophenone to Benzpinacol.
    4. Double Stage: ( Any four)
    i) Phthallic anhydride – Phthallimide – Anthranillic acid.
    ii) Acetophenone – Oxime – Acetanillide.
    iii) Phthalic anhydride – o – benzoyl benzoic acid anthraquinone.
    iv) Chlorobenzene – 2, 4 – dinitrochlorobenzene – 2,4-dinitrophenol.
    v) Benzoin – Benzil – Benzilic Acid
    vi) Acetanilide – p – Bromoacetanilide – p – Bromoaniline.
    5. Use of Computer - Chem Draw Chem-Sketch, ISI – Draw:
    Draw the structure of simple aliphatic, aromatic, heterocyclic compounds with
    different subsistent. Get the correct IUPAC name and predict the H1NMR signals.
    Ref. 14 (Relevant pages)
    · Pattern of practical examination
    Q. 1 Preparation (Single Stage) or Derivative 30 marks
    Q. 2. Techniques : Column or TLC or Steam Distillation 30 marks
    Q. 3 Assignment on computer 10 marks
    Q. 4. Oral 10 Marks.