AB
1
Course Syllabus
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Semester I:
3
4
FieldsValues
5
Date3/27/2022
6
Course CodeIC1010
7
Course NameIndustrial Organic Chemistry-I
8
Credits3
9
Pre-requisites (if any)Not
10
Nature of CourseTheory
11
Type of Coursecore
12
Targeted Program and yearBTech 1 and II
13
ContentsChemical process industry: Introduction, Overview and current status, Raw materials, manufacturing and engineering, Introduction to different industries by taking relevant examples. Basic products of industrial syntheses (Suitable examples: Methanol, Formaldehyde and Formic acid etc.), Pharmaceuticals (Classifications, Aspirin, Paracetamol, Ibuprofen, morphine etc.), Food chemicals (Vitamins, Food additives and preservatives), Agrochemicals (Suitable examples: Fertilizers, Pesticides, Herbicides etc.), Plastic (Suitable examples: bioplastics, thermoplastics etc.).
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References1. Industrial Organic Chemistry by Klaus Weissermel and Hans-Jurgen Arpe, 2003 WILEY‐VCH Verlag GmbH & Co. KGaA
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2. Handbook of Industrial Chemistry: Organic Chemicals by Mohammad Farhat AIi, Bassam M. El AIi, James G. Speight, 1st ed. New York: McGraw-Hill Education
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3. Industrial Organic Chemistry by Mark A. Banvenuto, Berlin; Boston: De Gruyter 2017
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Course ObjectiveThe course intends to expose the students with the fundamentals of industrial chemistry related to different industrial backgrounds.
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Justification:The course is designed in such a way that the student will learn about the synthesis and applications of common chemicals used in industrial setup.
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Semester II:
25
26
FieldsValues
27
Date3/27/2022
28
Course CodeIC1030
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Course NameIntroduction to Systematic Inorganic Chemistry & Applications
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Credits3
31
Pre-requisites (if any)not
32
Nature of Coursetheory
33
Type of Coursecore
34
Targeted Program and yearBTech 1 and II
35
Contents• Acids and bases: classification, Lewis acid and base concept, hard acid, hard base classification, Pearson’s HSAB concept and application; Oxidation and reduction: redox reactions, redox potential, • Electrochemical series, use of electrochemical series;
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• Metallic chains, sheets and clusters; Metal silicates, zeolites and polyoxo-metallates; Metals and alloys, ceramic materials, intermetallic compounds and zintl phases; • Chemistry of phosphorus, phosphorus oxides and phosphorus hydrides; Chemistry of oxyacids and oxyanion of nitrogen and phosphorus; Differences between the chemistry of nitrogen and phosphorus; Chemistry of the halogens: pseudo-halogen, inter-halogen; Oxides and oxyacids; Polyhalides; • Chemistry of the rare gases: Chemistry of xenon, structure and bonding of xenon compounds; • Non-aqueous solvents: types of solvents, general characteristics, reactions in non-aqueous solvents with reference to liquid NH3 and liquid SO2.
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ReferencesN. N. Greenwood and A. Earnshaw, Chemistry of the Elements, 2nd Ed., London: Butterworth Heinmann, 1997.
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Course Objective
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Justification:
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45
FieldsValues
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Date3/27/2022
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Course CodeIC1040
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Course NameThermodynamics-I
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Credits3
50
Pre-requisites (if any)not
51
Nature of CourseTheory
52
Type of CourseCore
53
Targeted Program and yearBTech 1 and II
54
ContentsThermodynamic properties and equilibrium, concepts of heat and work, zeroth law of thermodynamics; concept of temperature, energy and various forms of energy; internal energy, enthalpy; specific heats; first law applied to elementary processes, closed systems and control volumes, steady and unsteady flow analysis. Second Law of Thermodynamics, Carnot cycle and Carnot principles/theorems, Clausius inequality and concept of entropy; microscopic interpretation of entropy, the principle of increase of entropy, T-S diagrams; second law analysis of control volume; availability and irreversibility; third law of thermodynamics;
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Properties of Pure Substances; P-V-T behaviour of simple compressible substances, phase rule, thermodynamic property tables and charts, ideal and real gases, ideal gas equation of state and van der Waals equation of state; law of corresponding states, compressibility factor and generalized compressibility chart.
56
ReferencesPhysical Chemistry by Peter Atkins, Julio de Paula and James Keeler, 11the edition, 2018
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Physical Chemistry by Robert G. Mortimer, 3rd edition, 2008
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Course ObjectiveThe study of thermodynamics to understand the comprehensive macroscopic theory of the behavior of material systems
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Justification:The course is required to understand the properties and behavior of material systems and to apply this understanding in useful ways.
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61
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64
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FieldsValues
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Date3/27/2022
67
Course CodeIC1050
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Course NameIntroduction to Quantum Chemistry
69
Credits2
70
Pre-requisites (if any)Not
71
Nature of Coursetheory
72
Type of Coursecore
73
Targeted Program and yearBTech I and II
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ContentsThe motivation for Quantum mechanics: Historical background, postulates and general principles of quantum mechanics; Operators and their properties; Schrodinger equation, its application on some model systems : free-particle and particle in a box (1D and 3D), the harmonic oscillator, the rigid rotator, and the hydrogen atom; Approximate methods; Angular momentum: Eigenfunctions and eigenvalues of angular momentum operator, Spin- Pauli Principle; Born-Oppenheimer approximation; VB and MO theory, Application to H2+, H2 molecule
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ReferencesQuantum Chemistry by I. N. Levine, 7th edition, 2014
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Quantum Chemistry by McQuarrie, 1st (viva student) edition, 2018
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Physical Chemistry by Peter Atkins, Julio de Paula and James Keeler, 11the edition, 2018
78
Course ObjectiveUnderstanding the development and uses of quantum mechanics to understand dynamics of chemical structures and bonding.
79
Justification:The course is designed to discuss the quantum mechanical description of structure and bonding.
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82
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IC2080
84
85
FieldsValues
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Date3/27/2022
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Course CodeIC2080
88
Course NameTransport Properties
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Credits2
90
Pre-requisites (if any)not
91
Nature of Coursetheory
92
Type of Coursecore
93
Targeted Program and yearBtech I and II
94
ContentsIntroductory remarks on transport properties, The general equation for transport, Thermal conductivity in a gas, Collisions in a gas; The mean free path, Final expression for the thermal conductivity, Viscosity, Molecular diameters, Diffusion, Summary of transport properties in a gas, The nonsteady state, The Poiseuille Formula, The viscosimeter; Electrical transport; Conduction in metals, The Hall effect, The electrical current in ionic solutions, The measurement of conductivity in electrolytic solutions, The migration of ions;
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Transference numbers; Molar ion conductivities; Applications of conductance measurements; Stokes's law; Conductivities of the hydrogen and hydroxyl ions; Temperature dependence of the ion conductivities 
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ReferencesPhysical Chemistry by G. W. Castellan, 3rd edition, 1983
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Physical Chemistry by Robert G. Mortimer, 3rd edition, 2008
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Course ObjectiveUnderstanding of various transport phenomena of charged and neutral particles in gas, liquid phases
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Justification:The course is designed to provide fundamentals of transport phenomena
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101
102
103
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Semester III:
105
FieldsValues
106
Date3/27/2022
107
Course CodeIC2010
108
Course NameIndustrial Organic Chemistry-II
109
Credits3
110
Pre-requisites (if any)IC1010
111
Nature of CourseTheory
112
Type of CourseCore
113
Targeted Program and yearBTech-III
114
ContentsIndustrially relevant Vinyl-Halogen and Vinyl-Oxygen Compounds (Vinyl chloride, Vinylidene Chloride, Vinyl Fluoride, Trichloro- and Tetrachloroethylene, Vinyl Esters and Ethers etc.), Components for the synthesis of polyimides (various dicarboxylic acids and diamines, Lactams etc.), Industrially relevant chemicals derived from propene (Oxidation of propene, Acrolein, Allyl compounds, Acrylonitrile etc.), Industrially relevant Aromatics Production and Conversion, Industrially relevant benzene derivatives (Alkyl benzenes, Styrene, Phenol, Aniline etc.), Industrially relevant compounds derived from Oxidation of Xylene and Naphthalene (Phthalic Anhydride and Esters of Phthalic Acid and Derivatives)
115
References1. Industrial Organic Chemistry by Klaus Weissermel and Hans-Jurgen Arpe, 2003 WILEY‐VCH Verlag GmbH & Co. KGaA
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2. Handbook of Industrial Chemistry: Organic Chemicals by Mohammad Farhat AIi, Bassam M. El AIi, James G. Speight, 1st ed. New York: McGraw-Hill Education
117
3. Industrial Organic Chemistry by Mark A. Banvenuto, Berlin ; Boston : De Gruyter 2017
118
4. Modern Carbonylation Methods by Prof. László Kollár, 2008 Wiley‐VCH Verlag GmbH & Co. KGaA
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Course ObjectiveTo provide comprehensive knowledge of industrially relevant chemical transformations.
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Justification:The course is designed to provide extensive knowledge of synthesis and applications of chemicals used in the industrial sector.
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122
123
FieldsValues
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Date3/27/2022
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Course CodeIC2020
126
Course NameIntroduction to Biochemistry
127
Credits2
128
Pre-requisites (if any)none
129
Nature of CourseTheory
130
Type of CourseCore
131
Targeted Program and yearBtech
132
ContentsStructure, properties and reactions of mono- and di-saccharides; physicochemical properties of amino acids and peptides; structural features of proteins, nucleic acids, lipids, steroids, terpenoids, carotenoids, and alkaloids. Protein folding / misfolding and function; Enzyme kinetics, regulation and inhibition; Bioenergetics and metabolism;
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ReferencesReferences:
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1. Biochemistry by Raymond S. Ochs & Lehninger Principles of Biochemistry, 8th Edition
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2. Biochemistry by Stryer et.al. 9th edition
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Course ObjectiveThe course aim to teach the basics of biochemistry and prepare them for modern pharmacological applications
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Justification:Understanding the fundamentals of biochemistry is prerequisite for the advance level applications in drug design and development.
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141
142
FieldsValues
143
Date3/27/2022
144
Course CodeIC2011
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Course NameBasic Industrial Techniques Lab
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Credits2
147
Pre-requisites (if any)None
148
Nature of CourseLab
149
Type of CourseCore
150
Targeted Program and yearBTech II and BTech III
151
ContentsExperiments in Physical and Inorganic Chemistry covering first order and second order kinetics, activation energy, Freundlich adsorption, conductometric and pH metric titrations, distribution coefficient and equilibrium constant determination, phase diagram of a three-component system, viscosity determination, study of systems with lower and upper Critical Solution Temperature.
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ReferencesManuals and references will be provided from the chemistry lab
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1. Peter Atkins, P., and J. De Paula. Atkins’ physical chemistry. OUP Oxford, 2014.
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2. Allen J., Bard and Larry R. Faulkner. " Electrochemical methods- Fundamentals and applications." Wiley, 2000.
156
Course ObjectiveTo gain hands-on experience and practical realisation for the theoretical work
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To apply the basic knowledge on model systems to extract various physicochemical parameters
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Justification:Laboratory course provides ultimate experience to the students. Theoretical knowledge can be justified by performing laboratory experiments and to realize the deviations from the ideal behavior under real conditions
159
160
161
162
FieldsValues
163
Date3/27/2022
164
Course CodeIC2030
165
Course NameThermodynamics-II
166
Credits3
167
Pre-requisites (if any)IC1040
168
Nature of CourseTheory
169
Type of CourseCore
170
Targeted Program and yearBTechII
171
ContentsThermodynamic Relations, T-∆S relations, Helmholtz and Gibbs functions, Gibbs relations, Maxwell relations, Joule-Thomson coefficient, coefficient of volume expansion, adiabatic and isothermal compressibilities, Clapeyron and Clapeyron-Clausius equations.
172
Thermodynamic Cycles: Carnot vapor cycle, ideal Rankine cycle, Rankine reheat cycle, air-standard Otto cycle, air-standard Diesel cycle, air-standard Brayton cycle, vapor-compression refrigeration cycle,
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Ideal Gas Mixtures Dalton’s and Amagat’s laws, properties of ideal gas mixtures, air-water vapor mixtures and simple thermodynamic processes involving them; specific and relative humidities, dew point and wet bulb temperature, adiabatic saturation temperature, psychrometric chart.
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ReferencesThermodynamics and its Applications” by J W Tester and M Modell
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Thermodynamics: An Engineering Approach” by Michael A Boles
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Fundamentals of Engineering Thermodynamics” by M J Moran and H N Shapiro
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Course ObjectiveVarious thermodynamic relations, thermodynamical cycles, thermodynamical process, and applications
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Justification:The course is designed for students to gain knowledges on various thermodynamical cycles, and relations. The implications of the same is highly sought after in chemical industrial processes.
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180
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Semester IV
183
FieldsValues
184
Date3/27/2022
185
Course CodeIC2040
186
Course NameFood Technology
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Credits2
188
Pre-requisites (if any)None
189
Nature of CourseTheory
190
Type of CourseCore
191
Targeted Program and yearBTech II
192
ContentsCarbohydrates: structure and functional properties of mono-, oligo-, & poly- saccharides including starch, cellulose, pectic substances and dietary fibre. Proteins: classification and structure of proteins in food. Lipids: classification and structure of lipids, rancidity, polymerization and polymorphism. Food flavours: terpenes, esters, aldehydes, ketones and quinines. Nutrition: balanced diet, essential amino acids and essential fatty acids, protein efficiency ratio, water soluble and fat-soluble vitamins, role of minerals in nutrition, co-factors, anti-nutrients, nutraceuticals, nutrient deficiency diseases.
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ReferencesFood Chemistry. 4th edition, Belitz, H.-D., Grosch, Werner, Schieberle, Peter. Springer-Verlag Berlin Heidelberg, 2019 Principles of Food Chemistry. by deMan, J.M., Finley, J., Hurst, W.J., Lee, C. Springer International Publishing, 2018
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Course ObjectiveTo understand the food composition along with its physicochemical, nutritional, microbiological and sensory aspects.
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Processing and preservation of plant and animal foods; cereals, pulses, oilseeds, fruits vegetables, spices, meat, fish, poultry, sea food, milk and dairy products. Food safety, quality management and international food laws and regulations as well as importance of food engineering and packaging in food industry
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Justification:The course contents have been so crafted that it can keep pace with the rapidly growing food industry
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198
199
200
FieldsValues
201
Date3/27/2022
202
Course CodeIC2021
203
Course NameSynthesis and Separation Lab
204
Credits2
205
Pre-requisites (if any)none
206
Nature of CourseLab
207
Type of Coursecore
208
Targeted Program and yearBtech
209
Contents1) Separation of mixtures by Chromatography: Measure the Rf value in each case; a) Identify and separate the components of a given mixture of 2 amino acids (glycine, aspartic acid, glutamic acid, tyrosine or any other amino acid) by paper chromatography
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b) Identify and separate the sugars present in the given mixture by paper chromatography; 2) Synthesis of common industrial compounds involving two step reactions, (e.g. 4- bromo aniline, or 3-nitroaniline, or 4-amino benzoic acid, or 4-nitro benzoic acid)
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3) Preparation of paracetamol and its analysis; 4) Preparation of sulphacetamide of sulphonamide and its analysis; 5) Preparation of oils of winter green and its analysis; 6) Determination of ascorbic acid in vitamin C tablets by iodometric or coulometric titrations.
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7) Separation of a mixture of dyes by column chromatography; 8) Determination of alcohol contents in liquid drugs/galenical.
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References1. Vogel′s Textbook of Practical Organic Chemistry, 5th Ed. A. Vogel, et al., ed.,
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2. Working Manuals will be provided from the chemistry lab.
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Course ObjectiveTo gain hands-on experience and practical training
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Justification:The students will be exposed to the synthesis tools and techniques
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218
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220
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FieldsValues
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Date3/27/2022
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Course CodeIC 2050
224
Course NameCoordination Chemistry and Study of Transition Metal Complexes
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Credits2
226
Pre-requisites (if any)None
227
Nature of CourseTheory
228
Type of CourseCore
229
Targeted Program and yearBTech II
230
Contents •Crystal field theory, Splitting of d orbitals in linear, triangular, tetrahedral, square planar, trigonal bipyramidal, square pyramidal, octahedral and pentagonal bipyramidal fields of similar and dissimilar ligands.
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• Crystal field stabilization energies in weak field and strong field environments, octahedral site preference energy, tetragonal distortion and Jahn Teller effect. Shapes of complexes. Effect of crystal field stabilization on ionic radii, lattice energy, hydration enthalpy and stability of complexes (Irving Williams order). Kinetic aspects of crystal field stabilization, crystal field activation energy, labile and inert complexes.
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•Electronic spectra of metal complexes – determination of free ion terms of d1 to d9, microstates, determination of ground and all excited state terms of dn terms in octahedral and tetrahedral fields,
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• Orgel diagrams (qualitative approach), hole formalism, inversion and equivalence relations, selection rules for spectral transitions, d-d spectra and crystal field parameters, Nephelauxetic series, qualitative idea of Tanabe–Sugano diagrams, charge transfer spectra. Magnetic properties – elementary idea.
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References1. Concepts and Models in Inorganic Chemistry – Douglass, McDanniel & Alexander Coordination Chemistry
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2. Coordination Chemistry – S. F. A. Kettle, Inorganic Chemistry –A. G. Sharpe
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Course ObjectiveIntroduction to the fundamentals of transition metal and coordination chemistry
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Justification:This course is designed to provide basic concepts of transition metals and coordination compounds. It will build a foundation for students to learn advanced concepts of inorganic chemistry relevant to various industrial processes at later stages of the BTech program
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239
240
241
FieldsValues
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Date3/27/2022
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Course CodeIC2060
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Course NamePetroleum and Petrochemicals
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Credits2
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Pre-requisites (if any)No
247
Nature of CourseTheory
248
Type of CourseCore
249
Targeted Program and yearBTech II and III
250
Contents• Origin, formation and composition of petroleum, • petroleum processing: fractionation, blending of gasoline, gasoline treatment, kerosene treatment, treatment of lubes, petroleum wax and purification; • Thermal and catalytic processes: thermal cracking, catalytic cracking, catalytic reforming, naphtha cracking, coking, hydrogen processes, alkylation, isomerization processes; polymer gasoline, asphalt, upgradation of heavy crudes; • Specialty products: industrial gases, liquid paraffin, petroleum jelly; Sources of petrochemicals; Synthesis of methanol, formaldehyde, acetylene, synthetic gas, ethanol, ethylene, ethylene glycol, vinyl acetate, acrylic acid and acrylates, acrylonitrile, acetone, acetic acid, chloroprene, vinyl chloride, vinyl acetate, acrylonitrile, propylene, butadiene, butanes, isobutene, adipic acid, adiponitrile, benzene, toluene, xylene, phenol, styrene, phthalic acid, phthalic anhydride and their applications in chemical industry.
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ReferencesB. K. B. Rao, Modern Petroleum Refining Processes, 4th Ed., Oxford & IBH Publishing Co. Pvt Ltd., New Delhi, 2002.
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P. Wiseman, Petrochemicals, John Wiley & Sons, 1986.
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Course Objective
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Justification:
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257
258
259
260
FieldsValues
261
Date3/27/2022
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Course CodeIC2070
263
Course NamePolymer Science-I
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Credits3
265
Pre-requisites (if any)None
266
Nature of CourseTheory
267
Type of CourseCore
268
Targeted Program and yearBtech II and III
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Contents• Classification of polymers, Kinetics of polymerization, • Molecular weight of polymer and its determination, Some specific methods for molecular weight determination of biopolymers- gel filtration, SDS-PAGE for proteins, Agarose gel method for nucleic acids.
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• Thermodynamics of polymer solution: Polymer conformation. Molecular weights and molecular weight distributions and their determinations (viscometry, osmometry, light scattering, size-exclusion chromatography; • Principles of macromolecular synthesis: step-growth vs. chain-growth polymerizations. • Advanced synthetic techniques for controlling molecular weight dispersity in synthetic polymers- Living polymerization (living ionic, living radical and living ring-opening polymerizations); block copolymers-synthesis, microstructure, and applications; Conjugated polymers and their electrical and opto-electronic properties.
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ReferencesPrinciples of Polymer Chemistry, P.J. Flory, 2nd ed. 2000
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Polymer Science and Technology, Robert O. Ebewele, CRC Press,Illustrated edition,, 2000
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Course Objective
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Justification:
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276
277
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Semester V
279
FieldsValues
280
Date3/27/2022
281
Course CodeIC3010
282
Course NameMaterial Science-I
283
Credits3
284
Pre-requisites (if any)None
285
Nature of CourseTheory
286
Type of CourseCore
287
Targeted Program and yearBTech II, III and IV
288
ContentsThe course is designed to introduce fundamentals on solid-state materials that are suitable for applications to engineering systems.
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Course content:
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1. Translational symmetry, Bravais lattices, point & space group, Miller indices (planes and directions), basic concepts of powder & single-crystal X-ray and neutron diffraction; 2. Crystal chemistry of important solid-state structure types; 3. Bonding in solids, Pauling’s Rules, Bond Valence concept; 4. Point, line, planar, and bulk imperfections in crystalline solids
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5. Introduction to Nano (nanocrystalline solids); 6. Synthetic methodologies to prepare bulk and nanocrystalline solids
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7. Electrical properties of solids. 8. Band theory: metals, insulators, and semiconductors. 9. Bandgap engineering, doping, and semiconductor devices.
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References(a) Solid-state chemistry and its applications by Anthony R. West
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(b) Solid-state chemistry: an introduction by Lesley Smart and Elaine Moore
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(c) Elements of X-ray diffraction by B. D. Cullity.
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Course ObjectiveTo introduce to the world of Materials
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To gain knowledge on the structual aspects of materials
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To overview on the trend of emerging naomaterials
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To understand the structure-property relationships of materials
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Justification:From stone age to silicon age, materials contributed to the development of human civilization. Students must need to acquire knowledge on the synthesis of materials and their structural aspects leading to the functional properties. The current era of nanomaterials is no exception and advancement towards development of new materials continue to expand.
301
302
303
304
305
FieldsValues
306
Date3/27/2022
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Course CodeIC3013
308
Course NameNumerical and Computational Chemistry (Theory+Lab)
309
Credits3
310
Pre-requisites (if any)None
311
Nature of CourseTheory
312
Type of CourseCore
313
Targeted Program and yearBtech II, III and IV
314
ContentsProgramming principles using loops, arrays and functions; use of libraries; Numerical methods: truncation and round off errors; roots; interpolation; differentiation and integration; linear equations, matrix operations; curve fitting; ODEs; optimization; Application of numerical methods to chemical problems.
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Computational chemistry: A brief outline of molecular mechanics, semi-empirical approximations, ab initio methods, Density Functional Methods, basis sets, and Z-matrix; Application of these computational methods for prediction of structural and electronic properties of molecules, solid-state materials by using standard programs; computation of potential energy surfaces. Conformational analysis by molecular mechanics; Dynamical and structural studies of molecules using molecular dynamics simulations; Monte Carlo simulations of molecules; Molecular Docking Techniques.
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ReferencesFortran 90/95 for Science and Engineering, edition 2, S.J. Chapman, McGraw Hill
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Introduction to Numerical Computation, L. Eldén, L. Wittmeyer-Koch, H.B. Nielsen,
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J. Cramer, Essentials of Computational Chemistry: Theories and Models
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J. B. Foresman, A. Frisch, Exploring Chemistry with Electronic Structure Methods.
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R. Dronskowoski, R. Hoffmann, Computational Chemistry of Solid-state materials: A Guide for Material Scientists, Chemists, Physicists, and others.
321
Course Objective
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Justification:
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324
325
326
327
FieldsValues
328
Date3/27/2022
329
Course CodeIC3020
330
Course NameElectrochemical Energy Conversion
331
Credits3
332
Pre-requisites (if any)
333
Nature of CourseTheory
334
Type of CourseCore
335
Targeted Program and yearBTech (III or IV), M.Sc
336
ContentsThis course gives an insight to fundamental of electrochemistry; corrosion and electrodeposition of metals from the aspect of electrochemistry and the course will provide comprehensive exploration of all types of batteries and fuel cells and their applications.
337
Contents:
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Electrochemical cell - redox reaction, origin of electrode potential, Standard Hydrogen Electrode, EMF series, Reference electrodes, Concentration cells, Liquid Junction Potential, Applications of EMF, Conductivity of electrolyte solutions, Activity, Activity coefficient, Debye - Huckel - Onsager Equation, Kinetics- Over-potential, Butler Volmer equation, Tafel equation. Corrosion: Basics, chemical and electrochemical corrosion, corrosion control, Electrodeposition.
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Principles of Operation of Cells and Batteries; Electrochemical Principles and Reactions; Factors Affecting Battery Performance; Battery Design; Primary cells and Batteries; Fundamentals of Secondary Batteries: Advanced Lead-acid, Ni-based and lithium-ion batteries, next generation batteries, Materials for batteries, Electrode preparation, cell Assembly, electrochemical performance analysis, understanding of degradation mechanism and Safety. Fuel cells: Introduction to Fuel Cells: working principle, direct methanol fuel cells, Proton Exchange Membrane Fuel Cells, alkaline fuel cells, phosphoric acid, solid oxide, molten carbonate Fuel cells. Advanced batteries and fuel cells for UPS, Solar, Telecom, Aerospace, Grid and Electric Vehicle applications.
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References1. Peter Atkins, P., and J. De Paula. Atkins’ physical chemistry. OUP Oxford, 2014.
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2. Allen J., Bard and Larry R. Faulkner. " Electrochemical methods- Fundamentals and applications." Wiley, 2000.
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3. John O'M. Bockris, Amulya, K.N. Reddy, Maria E. Gamboa-Aldeco, Modern Electrochemistry 2A, Fundamentals of Electrodics, 2nd Edn, 2006.
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4. T. Ohtsuka, A. Nishikata, M. Sakairi, K. Fushimi, Electrochemistry for Corrosion Fundamentals, Springer, 2006.
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5. Kirby W. Beard. Linden's Handbook of Batteries, Fifth Edition (McGraw-Hill Education: New York, Chicago, San Francisco, Athens, London, Madrid, Mexico City, Milan, New Delhi, Singapore, Sydney, Toronto, 2019).
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6. Vladimir S. Bagotsky, Alexander M. Skundin and Yury M. Volfkovich (A.N. Frumkin Institute of Physical Chemistry and Electrochemistry of the Russian Academy of Science, Nanostructured Materials for Next-Generation Energy Storage and Conversion: Advanced Battery and Supercapacitors, Springer Nature, 10-Oct-2019 - Technology & Engineering - 472 pages.
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8. D. Pavlov, Lead-Acid Batteries: Science and Technology, Elsevier 31-May-2011 - Technology & Engineering - 656 pages.
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9. C. Vincent, Bruno Scrosati, Modern batteries, Elsevier, 26-Sep-1997 - Technology & Engineering - 368 pages.
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10. Paul Breeze, Fuel cells, 2017, Elsevier Science, 100 pages.
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Electrochemical Power Sources: Batteries, Fuel Cells, and Supercapacitors”
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By, John Wiley & Sons Inc, New Jersey, USA, 2015, 372 pages, ISBN: 978-1-118-46023-6.
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Course ObjectiveTo understand the basics of electrochemistry
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To apply such fundamental concepts in developing environmentally friendly energy storage devices
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To motivate students in exploring cutting-edge research based on advanced electrochemistry
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Justification:1) Electrochemistry has a rich historical background and the domain of applied electrochemistry is given the utmost importance. What is the essence of electrochemistry in addressing some of the pressing global issues related to energy? What kind of electrochemical approaches and methods can be suitable towards realizing the fossil-fuel free society will be discussed in this course.
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2) IC3060 may have a little bit of basic electrochemical aspects, but the current course is a way advanced and would encourage students to pursue cutting-edge research problems related to electrochemical energy storage and electrocatalysis, fuel cells,etc. IC3011 provides hands-on experience in using specific electrochemical techniques to provide practical knowledge to the students.
356
357
358
359
360
FieldsValues
361
Date3/27/2022
362
Course CodeIC3030
363
Course NameChemical Kinetics and Surface Chemistry
364
Credits3
365
Pre-requisites (if any)
366
Nature of CourseTheory
367
Type of CourseCore
368
Targeted Program and yearBTech III, IV, M.Sc
369
ContentsIntroduction to Chemical Kinetics: Order, molecularity,1st-2nd- 3rd –nth order derivations, half-life, determining the order of reaction, the effect of Temperature, Concentration, Pressure, Catalyst on Reaction Rate, Arrhenius equation, Kinetics of nuclear reactions, reversible /opposing reactions, consecutive /successive reactions, side/parallel reactions, steady-state approximation, chain reactions, collision-transition state theory.
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Aggregation and self-assembly; Colloids: Classification and preparation; Structure and stability; The electrical double layer, Micelles, and biological membranes; Determination of size and shape; Mean molar masses; Laser light scattering
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The growth and structure of solid surfaces, The extent of adsorption; The extent of adsorption; The rates of surface processes
372
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References1. K. J. Laidler, Chemical Kinetics, 3rd Ed., Pearson (2003)
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2. M. R. Wright, An Introduction to Chemical Kinetics, John Wiley (2004)
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3. P. Atkins, J. de Paula and J. Keeler, Atkins’ Physical Chemistry, 11th Ed., Oxfod University Press (2018).
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4. N. J. Turro, V. Ramamurthy and J. C. Scaiano, Modern Molecular Photochemistry of Organic Molecules, Viva Student Edition, Viva (2017).
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5. J. I. Steinfel, j. S. Francisco and W. L. Hase, Chemical Kinetics and Dynamics, 2nd Ed., Prentice Hall (1999).
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6. Puri, Late BR, I. R. Sharma, and Madam S. Pathania. Principles of physical chemistry. Vishal, 2013.
379
7. Rajaram, J., and J. C. Kuriacose. "Kinetics and mechanism of chemical transformation." (1993).
380
Course ObjectiveTo understand the reaction kinetics of homogeneous and heterogeneous
381
To understand the importance of surface chemistry in the heterogeneous catalysis to design certain industrial processes
382
To apply the concepts in the better design of catalysts for mitigating pollution effects by converting harmful gases to less harmful ones.
383
Justification:1) Thermodynamics provides feasibility of a reaction but kinetics provide rate at which reaction proceeds. Depending on the rate of a chemical reaction, experimental reaction conditions such as temperature and catalyst can be explored as optimal options. Most of the heterogeneous catalysis is linked to industrial processes and hence it is very important to study surface chemistry and active sites responsible for the chemical conversion. Indeed, a lot of fertilizers and chemicals are being produced industrially with the knowledge of chemical kinetics.
384
2) there is no overlap of this course with others and it remains the unique course
385
386
IC3040
387
FieldsValues
388
Date3/27/2022
389
Course CodeIC3040
390
Course NameSpectroscopy and Applications
391
Credits2
392
Pre-requisites (if any)none
393
Nature of CourseTheory
394
Type of CourseCore
395
Targeted Program and yearBTech II, III, IV, MSc
396
ContentsGeneral aspects of spectroscopy, Fundamentals and applications of the following methods: Nuclear Magnetic Resonance Spectroscopy: NMR phenomenon, spin 1/2 nuclei, 1H, 13C, 19F and 31P, Zeeman splitting, Boltzmann distribution, effect of magnetic field strength on sensitivity and resolution. 1H-NMR, chemical shift, anisotropic effects, chemical and magnetic equivalence, coupling constants. Karplus relationship of J on dihedral angle, first order splitting patterns and structure correlation. 13C NMR - natural abundance, sensitivity. NOE effects, 13C chemical shifts and structure correlations. IR spectroscopy: Basic principles of IR spectroscopy, functional group frequencies of various classes of organic compounds. Factors affecting the group frequencies. UV-Vis spectroscopy: basic principles, Electronic levels and types of electronic transitions in organic, effect of extended conjugation and Woodward-Fieser rules for calculation of absorption maximum. Mass spectrometry: Introduction, Basic principle, Instrumentation, isotope abundance, molecular ions, fragmentation processes of organic molecules and deduction of structural information. Problem on structure elucidation of organic compounds based in spectral data.
397
References1. Silverstein, Bassler and Morill: Spectrometric identification of organic compounds
398
2. Willim Kemp: Organic spectroscopy
399
3. Pavia, Lampman, Kriz, Vyvyan: Introduction to Spectroscopy
400
Course ObjectiveTo train the students for the structural analysis of the synthetic compounds
401
Justification:The student will learn the fundamentals of characterization tools and techniques
402
403
404
405
IC3011
406
FieldsValues
407
Date3/27/2022
408
Course CodeIC3011
409
Course NameIndustrial Chemical methods Lab
410
Credits1
411
Pre-requisites (if any)none
412
Nature of CourseLab
413
Type of CourseCore
414
Targeted Program and yearBTech II and III
415
ContentsMini-projects based on electro- and chemical- polymerization of aniline, study of the redox reactions and the different forms of PANI by cyclic voltammetry and UV-vis spectroscopy or preparation of silver nanoparticle colloids, and understanding the dependence of band ga on particle size using UV- vis spectroscopy, electrodeposition of Ni / NiOx films and study of their electrochemical and optical properties.
416
References: Manuals and references will be provided from the chemistry lab
417
Referencesreference manual will be provided
418
Course ObjectivePlanning, preparation and execution of small scale industrial chemistry experiment
419
Justification:To develop indipendent thinking skill, the course is designed.
420
421
422
423
424
Semester VII
425
FieldsValues
426
Date3/27/2022
427
Course CodeIC4010
428
Course NameIntroduction to Drug Design
429
Credits2
430
Pre-requisites (if any)none
431
Nature of Coursetheory
432
Type of Course
433
Targeted Program and yearBTech-4 year, MSc
434
ContentsPrinciples of Drug Discovery, Targets for drug discovery, and Identification of Lead Compounds; Physiochemical Properties of Drugs (Absorption, Distribution, Metabolism); Drug Receptor interactions; enzymes as drug targets, Drug design strategies, Structure-Based Drug Design; Use of chemoinformatics in drug design, Strategies for Organic Drug Synthesis; Combinatorial Chemistry; Prodrugs and drug delivery systems, Illustration of drug development through specific examples, Drug resistance, Drug synergism and combination therapy.
435
ReferencesReferences:
436
1) Chemical Engineering in the Pharmaceutical Industry: Drug Product Design, Development, and Modeling by Mary T. am Ende (Editor), David J. am Ende (Editor). Wiley
437
2) Burger's Medicinal Chemistry, Drug Discovery and Development, 8 Volume Set. Volumes 1 – 8 Donald J. Abraham School of Pharmacy, Virginia Commonwealth University, Richmond, Virginia.
438
3) Silverman, R. B., The Organic Chemistry of Drug Design and Drug Action, 2nd Edition, 2004, ISBN: 0-12-643732-7, Academic Press
439
4) Organic Medicinal and Pharmaceutical chemistry. By Wilson and Gisvold's (English, Paperback, Beale John M)
440
5) Williams, D. A.; Lemke, T. L., Foye's Principles of Medicinal Chemistry. 5th ed.; Wolters Kluwer Health (India) Pvt. Ltd.: 2006.
441
Course ObjectiveTo update the students regarding drug development tools and techniques
442
Justification:The students will be taught about the rationale behind the drug design and development
443
444
445
446
447
FieldsValues
448
Date3/27/2022
449
Course CodeIC4011
450
Course NameTechniques in Industrial Chemistry Lab
451
Credits2
452
Pre-requisites (if any)None
453
Nature of CourseLab
454
Type of CourseCore
455
Targeted Program and yearB. Tech. (III and IV)
456
Contents• Synthesis and characterization of inorganic compounds in the diverse areas of Inorganic Chemistry such as Coordination Chemistry,
457
• Organometallic Chemistry and Bioinorganic Chemistry etc. Characterization:
458
• quantitative and qualitative determination of ligand and metal, use of spectral techniques (UV-visible, FT-IR, NMR, ESR, magnetic moment, analytical methods (conductance, TGA, DSC, cyclic voltammetry).
459
References1. Synthesis and Technique in Inorganic Chemistry: A Laboratory Manual, Gregory S. Girolami, Thomas B. Rauchfuss and Robert J. Angelici. University Science Books.
460
2. Synthetic methods of organometallic and inorganic chemistry ed. by Wolfgang A. Herrmann, Georg Thieme Verlag, New York, 1997, Vol 7 and 8 3.
461
3. Vogel’s qualitative inorganic analysis, by Svehla, G. Publisher: Harlow: Longman, 1996. 4. Vogel’s textbook of quantitative inorganic analysis: including elementary instrumental analysis. By: Arthur Israel Vogel; John Bassett Publisher: London; New York: Longman, 1978.
462
Course ObjectiveThis advanced laboratory course aims to introduce students to the experimental aspects of industrial inorganic chemistry such as synthesis and characterization of coordination, bioinorganic, and organometallic compounds.
463
Justification:This practical course is required to train students in dealing with the characterization of various types of industry relevant inorganic compounds.
464
465
466
467
468
FieldsValues
469
Date3/27/2022
470
Course CodeIC4010
471
Course NameMaterials Science-II
472
Credits3
473
Pre-requisites (if any)IC3010
474
Nature of CourseTheory
475
Type of CourseCore
476
Targeted Program and yearBTech IV, M.Sc
477
ContentsThe course is designed to gain in depth knowledge on the physical properties of solid-state materials and their applications to engineering systems, characterization techniques and application.
478
Course content: 1. Magnetism & magnetic materials 2. Thermal and optical properties of solids 3. Superconductors, thermoelectric, photoconductors, solar cell, and battery materials 4. Properties of important metals oxides and chalcogenides for catalytic applications.
479
5. Introduction to nanoscience, nanotechnology; 6. Synthesis of Nanomaterials by Physico-chemical approaches.
480
7. Advanced Characterization Methods: X-ray diffraction and Microscopy methods, Optical Absorption and Emission Spectroscopy, Thermogravimetric Analysis, X-ray photoelectron spectroscopies, Raman spectroscopies. 8. Application of nanomaterials and safety.
481
Referencesa) G. A. Ozin and A. C. Arsenault, Nanochemistry-A Chemical Approach to Nanomaterials -, RSC Publishing, Cambridge, 2006.
482
b) G. Cao and Y. Wang, Nanostructures and Nanomaterials-Synthesis, Properties, and Applications, 2nd Edition, https://doi.org/10.1142/7885, Pages: 596, 2011,
483
e) Solid-state chemistry and its applications by Anthony R. West; 2014, Student edition
484
f) Solid-state chemistry: an introduction by Lesley Smart and Elaine Moore
485
Course ObjectiveTo gain knowledge on tools for characterisation of materials
486
To understand structure-property relationships of advanced materials
487
To study the functional properties of materials and further apply them in specific applications
488
Justification:1) Materials development advances human society. New types of materials are being discovered from time and time. It is alos very important to design materials as per specific application requirement. Therefore, characterisation of materials remain core of the subject which help guide for the better design of materials with intended properties. Understanding of different physicochemical properties of materials is very much required for the rational design of smart functional devices.
489
2) IC 3010 deals with the structural aspects and fundamental design aspects of materials. The current course deals with the characterisation and functional properties of materials
490
491
492
IC4030
493
FieldsValues
494
Date3/27/2022
495
Course CodeIC4030
496
Course NamePolymer Science-II
497
Credits3
498
Pre-requisites (if any)None
499
Nature of CourseTheory
500
Type of CourseCore
501
Targeted Program and yearBTech III and IV and MSc
502
Contents• Commodity and general-purpose thermoplastics: PE, PP, PS, PVC, Polyesters, Acrylic, PU polymers. Engineering Plastics: Nylon, PC, PBT, PSU, PPO, ABS, Fluoropolymers Thermosetting polymers: PF, MF, UF, Epoxy, Unsaturated polyester, Alkyds. Natural and synthetic rubbers: Recovery of NR hydrocarbon from latex, SBR, Nitrile, CR, CSM, EPDM, IIR, BR, Silicone, TPE.
503
• Difference between blends and composites, their significance, choice of polymers for blending, blend miscibility-miscible and immiscible blends, • thermodynamics, phase morphology, • polymer alloys, polymer eutectics, plastic-plastic, rubber-plastic and rubber-rubber blends, FRP, particulate, • long and short fibre reinforced composites., Polymer compounding-need and significance, different compounding ingredients for rubber and plastics, • Cross-linking and vulcanization, vulcanization kinetics.
504
• Flow of Newtonian and non-Newtonian fluids, different flow equations, dependence of shear modulus on temperature, molecular/segmental deformations at different zones and transitions.
505
• Measurements of rheological parameters by capillary rotating, parallel plate, cone-plate rheometer.
506
• Visco-elasticity-creep and stress relaxations, mechanical models, control of rheological characteristics through compounding, rubber curing in parallel plate viscometer, ODR and MDR.,
507
• Compression molding, transfer molding, injection molding, blow molding, reaction injection molding, extrusion, pultrusion, calendaring, rotational molding, thermoforming, rubber processing in two-roll mill, internal mixer.
508
• Mechanical-static and dynamic tensile, flexural, compressive, abrasion, endurance, fatigue, hardness, tear, resilience, impact, toughness.
509
• Conductivity-thermal and electrical, dielectric constant, dissipation factor, power factor, electric resistance, surface resistivity, volume resistivity, swelling, ageing resistance, environmental stress cracking resistance.
510
ReferencesPrinciples of Polymer Chemistry, P.J. Flory, 2nd ed. 2000
511
Polymer Science and Technology, Robert O. Ebewele, CRC Press,Illustrated edition,, 2000
512
Course Objective
513
Justification:
514
515
516
IC4016
517
FieldsValues
518
Date3/27/2022
519
Course CodeIC4016
520
Course NameIndustry Lecture Series
521
Credits1
522
Pre-requisites (if any)not
523
Nature of CourseSeminar
524
Type of Coursecore
525
Targeted Program and yearBTech III and IV, MSc
526
ContentsA series of lectures will be conducted at the department inviting prominent industry persons. It is mandatory for the BTech students to attend and interact with the speaker.
527
ReferencesNot required
528
Course ObjectiveSeminars for students to be familiarize with industry updates
529
Justification:
530
531
532
533
534
Semester VIII
535
536
FieldsValues
537
Date3/27/2022
538
Course CodeIC4040
539
Course NameIndustrial Pollution and Chemical Industrial safety
540
Credits3
541
Pre-requisites (if any)None
542
Nature of CourseTheory
543
Type of CourseCore
544
Targeted Program and yearBTech III and IV
545
ContentsCPCB Guidelines, Air and Noise Pollution,
546
Water pollution- ASP, ETP, etc
547
Solid Waste
548
Emission and control methods in the Production of Sulfuric Acid, Production of Nitrates-Containing Fertilizers, Lime Production, Soda Production, NaOH/Cl2 by electrolysis, Cement, Pharmaceutical Industry, Bulk Organic Chemical Industry
549
Water Pollution: Identification, quantification and analysis of wastewater, Classification of different treatment methods into physico-chemical and biochemical techniques, Physico-chemical methods, General concept of primary treatment, Liquid-solid separation, Design of a settling tank, Neutralization and flocculation, Disinfection, Biological methods, Concept of aerobic digestion, Design of activated sludge process, Concept of anaerobic digestion,
550
Air Pollution: Classification of air pollutants, Nature and characteristics of gaseous and particulate pollutants, Analysis of different air pollutants, Description of stack monitoring kit and high volume sampler, Atmospheric dispersion of air pollutants, Gaussian model for prediction of concentration of pollutant down wind direction, Plume and its behavior, Operating principles and simple design calculations of particulate control devices, Brief concepts of control of gaseous emissions by absorption, adsorption, chemical transformation and combustion.
551
Solid Wastes: Analysis and quantification of hazardous and non-hazardous wastes, Treatment and disposal of solid wastes, Land filling, Leachate treatment, Incineration. Environmental Management System: Environment impact assessment, Its concept and constituents, Environmental audit, ISO-14000 system.
552
ReferencesHand Book of “Industrial Safety and Health, Trade and Technical Press Ltd. Morden,U.K.1980.
553
William Handley, Industrial Safety Hand Book, McGraw-Hill Book Company 2nd Edition, 1969.
554
Fawatt,H.H.and Wood, W.S. Safety and Accident Prevention in Chemical Operation,Interscience,1965.
555
S.P.Mahajan, “Pollution Control in Process Industries” Tata McGraw Hill, NewDelhi1985.
556
K.S.N.Raju, “Chemical Process industry safety” Tata McGraw Hill, NewDelhi 2006.
557
Course Objective
558
Justification:
559
560
561
FieldsValues
562
Date3/27/2022
563
Course CodeIC4050
564
Course NameChemical Industrial separation techniques
565
Credits2
566
Pre-requisites (if any)Not
567
Nature of CourseTheory
568
Type of CourseCore
569
Targeted Program and yearBtech III, IV, MSc
570
ContentsRaoult’s law, distillation curves, Liquid-Liquid separation, Azeotropic distillation, Basics of Chromatography, LC, LC-MS-MS, HPLC, Detectors for HPLC, GC, detectors for GC, GC-MS-MS, GPC, IC.
571
ReferencesVogel, Arthur Israel, and George Harold Jeffery. Vogel's textbook of quantitative chemical analysis. Wiley, 1989.
572
Industrial Separation Processes, Fundamentals by André B. de Haan, H. Burak Eral and Boelo Schuur, 2nd edition, 2020.
573
Course ObjectiveLiquid-Liquid Extraction, Industrial membrane separation technologies, Industrial Crystallization, Fixed and fluid bed full scale chromatography
574
Justification:Separation processes on an industrial scale account for well over half of the capital and operating costs in the chemical industry. Knowledge of these processes is key for every student of chemical or process engineering.
575
576
577
578
579
List of Electives
580
581
FieldsValues
582
Date3/27/2022
583
Course Code IC3023
584
Course NameMachine Learning in Chemistry
585
Credits2
586
Pre-requisites (if any)
587
Nature of CourseTheory and Lab
588
Type of CourseCore
589
Targeted Program and yearBtech II, III, IV
590
ContentsArtificial intelligence (AI) rapidly changes many aspects of chemical sciences, from drug discovery, material design, and the discovery of new reactions and molecules till the acceleration of computer sciences and robotics for chemical applications. This course will cover the key aspects of AI and modern chemoinformatics and how they are applied on chemical sciences.
591
ReferencesChemoinformatics: Basic Concepts and Methods Edited by Engel and Gasteiger, (Wiley-VCH Verlag GmbH & Co., 2018).
592
Course Objective
593
Justification:
594
595
596
597
598
FieldsValues
599
Date3/27/2022
600
Course CodeIC3060
601
Course NameAdvanced Inorganic Chemistry
602
Credits3
603
Pre-requisites (if any)None
604
Nature of CourseTheory
605
Type of CourseElective
606
Targeted Program and yearBTech III & M.Sc I
607
ContentsBasic Bonding Theory, Crystal Field Theory and Molecular orbital Theory,
608
• Molecular Symmetry and Character Tables and their Application to Vibrational and Electronic spectroscopy, Selection Rules,
609
• Reaction Mechanism (Redox, Photochemistry, Ligand substitution reactions),
610
• Acid-Base and Donor-Acceptor Chemistry, Magneto-Chemistry, Organometallic Chemistry and Bioinorganic chemistry.
611
• Applications to current research problems in inorganic and solid-state chemistry.
612
References1. Inorganic Chemistry by Catherine E. Housecroft and Alan G. Sharpe; Physical Inorganic Chemistry by S F A KETTLE
613
2. Advanced Inorganic Chemistry, 6th Edition by F.
614
Albert Cotton, Geoffrey Wilkinson, Carlos A. Murillo, Manfred Bochmann.
615
Course ObjectiveThis course aims to offer advanced aspects of inorganic chemistry including structural, bonding, reaction mechanism, spectroscopic, and magneto-characterization of the organometallic, coordination compounds, and extended inorganic solids.
616
Justification:The course is designed to provide advanced concepts of inorganic chemistry, which is critical to design and fine-tune the properties of inorganic compounds relevant to industrial applications such as catalytic properties and value added inorganic materials.
617
618
619
620
621
FieldsValues
622
Date3/27/2022
623
Course CodeIC3070
624
Course NameIndustrial Heterogeneous catalysis
625
Credits3
626
Pre-requisites (if any)not
627
Nature of Coursetheory
628
Type of Courseelective
629
Targeted Program and yearBTech II, III and IV
630
ContentsIntroduction to Heterogeneous catalysis-Theory, Kinetic modelling, L-H and E-R mechanism. Electronic and Geometric factors, Industrial catalytic applications of Zeolites, Aluminophosphates, Mesoporous materials, Aminophosphates, Hydrotalcite, clays, Nanocomposites and Metal organic Frameworks. Nanoparticles for heterogeneous catalysis
631
Catalysts Preparation Methods: Solid-Solid (Ceramic Method) Solid from Liquid- Sol-gel Method; Co-Precipitation Method; Hydrothermal Method, Chemical Vapor deposition Method.
632
Characterization methods: Isotherm models, BET, BJH. TPD, TPD, TRP, Metal dispersion.
633
Solid acids/bases/redox and multifunctional catalysts: Applications of Solid acids: Alkylation, Cracking, Isomerization, Aromatization, Methanol to olefin reaction. Solid basic catalysis. Solid redox catalysts: Phenol & Benzene hydroxylation, Ammoxidation, Alkane oxidation, Alcohol oxidation, Alkene epoxidation. Oxidative dehydrogenation, Electrocatalysis.
634
Other Industrially important catalysts and processes: Wilkinson catalyst, Zeigler Natta catalyst, Fisher trope synthesis, Heck reaction, Suzuki coupling reaction, Haber process, Bio-diesel production, Photocatalysis.
635
Enzymatic catalysis: Enzymatic catalysis, Kinetics, General Mechanism, Mechanisms for the Inhibition of Enzyme Catalysis, Advantages, LImitations, and Applications.
636
References1. Catalysis: Principles and Applications, B. Viswanathan, S. Sivasanker, A.V. Ramaswamy, Narosa Publishing House, New Delhi 2007.
637
2. Industrial Catalysis A Practical Approach, Jens Hagen, Wiley-VCH, Verlag GmbH & Co. KGaA, 2006.
638
Course ObjectiveHeterogeneous catalysis, kinetic models, catalysts, mechanisms, examples and applications.
639
Justification:Heterogeneous catalysis is the back bone of chemical industry. The course is designed to enhance the understanding of the students on the current advancements of industrial catalysts.
640
641
642
643
644
FieldsValues
645
Date3/27/2022
646
Course CodeIC4060
647
Course NameMolecular Spectroscopy
648
Credits2
649
Pre-requisites (if any)not
650
Nature of CourseTheory
651
Type of Courseelective
652
Targeted Program and yearBTech III and IV, MSc
653
ContentsRegion of spectrum, spectral lines intensity and broadening, Microwave spectrum of rigid and non-rigid rotator, Principle of microwave oven; Vibrational spectra of harmonic and anharmonic oscillator, Vibrations of polyatomic molecules, group frequencies and its applications, instrumental methods. Raman spectroscopy and instrumentation, structure determination; Principles of UV-VIS spectroscopy and instrumentations; Principles and methodology of spin resonance spectroscopy: NMR and ESR; Magnetic resonance imaging (MRI).
654
References1. Physical Chemistry by Peter Atkins and Julio de Paula, James keeler, 11th edition, 2018
655
2. Fundamentals of molecular spectroscopy by Banwell, 4th edition, 2017
656
Course ObjectiveThe origin of interaction between radiation and matter, fundamental of molecular energy levels, absorption, instrumentations and applications
657
Justification:Analytical methods based on spectroscopy provides one of the most accurate methods. the course is designed to provide knowledge from fundamental to applications.
658
659
660
661
FieldsValues
662
Date3/27/2022
663
Course CodeIC4070
664
Course NameMetals in Biological Systems and Biochemical Processes
665
Credits2
666
Pre-requisites (if any)None
667
Nature of CourseTheory
668
Type of CourseElective
669
Targeted Program and yearBTech III and IV, M.Sc
670
ContentsMetal ions in biology: metallo-proteins and enzymes containing Mg, Ca, V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Mo and W ions. heme and non-heme systems, Peptide and nucleotide hydrolytic enzymes, Metal environment, electronic, magnetic and redox properties; fixation of N2, water-oxidation reactions, Synthetic models for the structure and function of the above enzymes, syntheses of ligand-metal complexes, reactivity of O2, CO, NO, N2; mechanistic aspects, high-valent metal-oxo (Fe-, Mn- and Cu) systems, Interaction of metal ions with nucleotides and peptides, hydrolysis of phosphate and amide groups, Metal based drugs, environmental applications and toxic effects.
671
ReferencesPrinciples Of Bioinorganic Chemistry Hardcover by Stephen J. Lippard, Jeremy M. Berg
672
Course ObjectiveThis course offers fundamental aspects of the metal ions involved in biological processes, which include studying chemical, redox, electronic, and their biological properties.
673
Justification:This course is designed to explore the chemistry of metals ions involved in important biological processes. This course will be useful for students to design new bioinspired molecules and to develop new routes to synthesize them in bulk scale for various important applications such as environmental remediation, green energy production, etc.
674
675
676
677
678
FieldsValues
679
Date3/27/2022
680
Course CodeIC4080
681
Course NameSynthetic Methodology in Organic Chemistry
682
Credits2
683
Pre-requisites (if any)
684
Nature of CourseTheory
685
Type of CourseElective
686
Targeted Program and yearBTech-VII/VIII, MSc
687
ContentsBasic retrosynthetic analysis: terminology associated with, prostereoisomerism, homo, enantio, diastereo ligands and faces, stereoselective synthesis.
688
Nucleophilic C-C bond forming reactions: organometallic reagents of lithium, magnesium, copper, chromium and iron, ylides of sulfur and nitrogen, Tebbe’s reagent. Enolates, kinetic and thermodynamic enolates, enolate condensation reactions like Claisen, Dieckmann, Knoevenegal, Stobbe, Darzen glycidic ester. Umpolung reagents, definition of umpolung, acyl anion equivalent, equivalents of ketene, RCOCH2+, RCOCH2CH2CH2+, RCOCH2CH2CH2- etc.
689
C-C bond formation via free radicals and carbenes: methods of generation of free radicals and carbenes, reactions of free radicals, coupling, addition, substitution, fragmentation and rearrangements.
690
C-C bond formation using tin reagents: Protecting groups, protection of hydroxyl, carboxyl, carbonyl, amino groups. Protection of carbon-carbon multiple bonds. Illustration of protection and deprotection in synthesis.
691
ReferencesReferences:
692
1. F. A. Carey and R. I. Sundberg, Advanced Organic Chemistry, Part A and B, 5th edition, Plenum Press, 2007.
693
2. S. Warren, Designing Organic Synthesis, John Wiley, 2009.
694
3. S. G. Davies, Organotransition Metal Chemistry, Application to Organic Synthesis, Pergamon Press, 1984.
695
4. R. K. Mackie and D. M. Smith, Guidebook to Organic Synthesis, ELBS, 1991.
696
5. Michael B. Smith, Organic Synthesis, McGraw Hill, 1994.
697
Course ObjectiveThe students will learn the advanced organic tools and techniques
698
Justification:Hardcore chemistry requires strong hold on synthetic organic chemistry
699
700
701
702
703
704
705
706
FieldsValues
707
Date3/27/2022
708
Course Code IC4100
709
Course NameApplied Statistical Methods and the Chemical Industry
710
Credits2
711
Pre-requisites (if any)
712
Nature of CourseTheory
713
Type of CourseElective
714
Targeted Program and yearBTech III and IV, MSc
715
ContentsQuality of Analytical Measurements-Propagation of error, Sampling strategy, Quality control methods-property control charts, precision control charts, collaborative tests and uncertainty of measurements, Significance tests: Comparison tests, outliers, ANOVA calculations.
716
Analytical methods Metrological Quality: Various types of analytical methods, regression analysis, Limit of detection, Limit of quantification, Random error, Calibration of equipment and instruments. Curvilinear and outlier analysis.
717
Standard Method Development and Validation: Optimization of experimental procedures in analytical chemistry, Standard addition, External standard, internal standard and dilution methods, response surfaces, specific examples, experimental design-fractional factorial designs. Validation testing parameters and their calculation with numerical examples
718
References1. Quality Assurance and Quality Control in the Analytical Chemical Laboratory, Piotr Konieczka and Jacek Namiesnik, CRC Press, 2009 and 2nd Edition.
719
2. Quality Assurance in the Analytical Chemistry Laboratory, D. BrynnHibbert, Oxford University Press, New York, 2007 and 1st Edition.
720
Course Objective
721
Justification:
722
723
724
725
726
FieldsValues
727
Date3/27/2022
728
Course Code IC4110
729
Course NameIntroduction to Toxicology
730
Credits2
731
Pre-requisites (if any)
732
Nature of CourseTheory
733
Type of CourseCore
734
Targeted Program and yearBtech III and IV
735
ContentsStudents examine basic concepts of toxicology as they apply to the effects of environmental agents, e.g. chemicals, metals, on public health. We discuss the distribution, cellular penetration, metabolic conversion, and elimination of toxic agents, as well as the fundamental laws governing the interaction of foreign chemicals with biological systems.
736
A survey of general principles underlying the effects of toxic substances on biological systems, including consideration of the history, scope and applications of toxicology, toxicant exposure, the mechanisms of toxic action, and some major types of toxicants
737
ReferencesHodgson, Ernest, ed. A textbook of modern toxicology. John Wiley & Sons, 2004.
738
Hayes, A. W., & Kruger, C. L. (Eds.). (2014). Hayes' principles and methods of toxicology. Crc Press.
739
Course Objective
740
Justification:
741
742
743
744
745
FieldsValues
746
Date3/27/2022
747
Course Code IC4013
748
Course NameMATLAB and Mathematical Computation
749
Credits2
750
Pre-requisites (if any)Not
751
Nature of CourseCombined theory and Lab
752
Type of Courseelective
753
Targeted Program and yearBtech III and IV, MSc
754
ContentsVariables, arrays, conditional statements, loops, functions, and plots are covered in a project-based style where much of the learning happens away from the classroom. Students are expected to spend about 4 hours per week on homework. At the end of the course, students should be able to use MATLAB in their own work, and be prepared to deepen their MATLAB programming skills and tackle other languages for computing, such as Java, C++, or Python.
755
References1. MATLAB Programming for Engineers, Stephen J. Chapman, 6th edition, 2020
756
2. Programming for Engineers: A Foundational Approach to Learning C and Matlab, Aaron R. Bradley,1st Edition, 1998
757
Course ObjectiveTo teach numerical solution to problems relevant to chemical industry and beyond.
758
Justification:Engineers and scientists need a programming language that lets them express matrix and array mathematics directly. Linear algebra in MATLAB is intuitive and concise
759
760
761
762
763
764
FieldsValues
765
Date3/27/2022
766
Course Code IC4120
767
Course NameBatteries and Fuel cells
768
Credits3
769
Pre-requisites (if any)not
770
Nature of Coursetheory
771
Type of Courseelective
772
Targeted Program and yearBtech III and IV, MSc
773
ContentsPrinciples of Operation of Cells and Batteries; Electrochemical Principles and Reactions; Factors Affecting Battery Performance; Battery Design; Primary cells and Batteries; Fundamentals of Secondary Batteries: Advanced Lead-acid, Ni-based and lithium-ion batteries, next generation batteries, Materials for batteries, Electrode preparation, cell Assembly, electrochemical performance analysis, understanding of degradation mechanism and Safety. Fuel cells: Introduction to Fuel Cells: working principle, direct methanol fuel cells, Proton Exchange Membrane Fuel Cells, alkaline fuel cells, phosphoric acid, solid oxide, molten carbonate Fuel cells. Advanced batteries and fuel cells for UPS, Solar, Telecom, Aerospace, Grid and Electric Vehicle applications.
774
References1. Kirby W. Beard. Linden's Handbook of Batteries, Fifth Edition (McGraw-Hill Education: New York, Chicago, San Francisco, Athens, London, Madrid, Mexico City, Milan, New Delhi, Singapore, Sydney, Toronto, 2019).
775
2. Vladimir S. Bagotsky, Alexander M. Skundin and Yury M. Volfkovich (A.N. Frumkin Institute of Physical Chemistry and Electrochemistry of the Russian Academy of Science, Russia) Electrochemical Power Sources: Batteries, Fuel Cells, and Supercapacitors”
776
By, John Wiley & Sons Inc, New Jersey, USA, 2015, 372 pages, ISBN: 978-1-118-46023-6.
777
3. Ying-Pin Chen, Sajid Bashir, Jingbo Louise Liu, Nanostructured Materials for Next-Generation Energy Storage and Conversion: Advanced Battery and Supercapacitors, Springer Nature, 10-Oct-2019 - Technology & Engineering - 472 pages.
778
Course ObjectiveThis course is a guide to the evolution of the use of electrochemistry to generate energy and power.
779
Justification:The course will provide comprehensive exploration of all types of batteries and fuel cells and their applications.
780
781
782
783
784
FieldsValues
785
Date3/27/2022
786
Course CodeIC4130
787
Course NameNuclear Chemistry
788
Credits3
789
Pre-requisites (if any)not
790
Nature of Coursetheory
791
Type of CourseElective
792
Targeted Program and yearBTech III, IV, MSc
793
Contents• Nuclear Chemistry Introduction: Basic Concepts,
794
• Elementary Particles, and Decay Types,
795
• Nuclear Properties: Nuclear masses and binding energies,
796
• Chemistry of Actinide and Trans-actinide elements, Radioactive decay Kinetics (α- and β-decay and γ-ray decay), Nuclear Reactions, Nuclear Fuel Cycle, and Nuclear Reactor,
797
• Separation Techniques for the Nuclear Wastes.
798
References1. Modern Nuclear Chemistry, Walter D. Loveland, David J. Morrissey, Glenn T. Seaborg, Second Edition, 2017
799
2. Nuclear and Radiochemistry, József Kónya and Noémi M. Nagy, Second Edition, 2018
800
Course ObjectiveThe course explains the basic principles and applications of the primary areas of nuclear and radiochemistry
801
Justification:The course includes nuclear medicine and chemical aspects of nuclear power plants, namely the problems of nuclear wastes and nuclear analysis, with the analytical methods based on the interactions of radiation with matter.
802
803
804
805
806
FieldsValues
807
Date3/27/2022
808
Course CodeIC4140
809
Course NameMedicinal Chemistry
810
Credits2
811
Pre-requisites (if any)
812
Nature of CourseTheory
813
Type of CourseElective
814
Targeted Program and yearBtech III and IV
815
ContentsHistory and development of medicinal chemistry. An Introduction to Drugs and their action – Source of drugs, classification and route of administration and drug action. Selected Examples of Drug Action at some Common Target Areas - Examples of drugs that target cell membranes, enzymes, receptors, and nucleic acids. Pharmacokinetics and Drug metabolism - Introduction, metabolic routes, and models of drug administration
816
ReferencesFundamentals of Medicinal Chemistry, by Gareth Thomas
817
Foye’s Principles of Medicinal Chemistry
818
Wilson and Giswold’s Organic medicinal and Pharmaceutical Chemistry.
819
Course Objective
820
Justification: