CSIR UGC NET Syllabus 201819 (June) LS, MS, CS, PS, ES Exam Pattern PDF
CSIR UGC NET Syllabus 2018
CSIR UGC NET Syllabus 2018:
Download CSIR UGC NET Syllabus from
below! The detailed CSIR UGC NET June exam syllabus of Life Sciences (LS),
Mathematical Sciences (MS), Chemical Sciences (CS), Physical Sciences (PS), and
Earth Sciences (ES) Exam is available on this page.
As per the official notification
CSIR will going to conduct the Joint CSIRUGC Test on Sunday 17th June,
2018(Tentative). So checkout the updated CSIR UGC NET June exam Syllabus and
exam pattern from the beneath section of this page.
CSIR UGC NET
Syllabus With Exam Pattern
CSIRUGC NET Exam
for Science stream is conducted by CSIR in following areas: Chemical Sciences,
Earth Sciences, Life Sciences, Mathematical Sciences and Physical Sciences. We
have also provided the direct links to download the Council of Scientific &
Industrial Research exam syllabus.
You can get further details regarding
CSIR UGC NET Syllabus 2018 2019 by scrolling down this page which is well created
by the team of www.privatejobshub.in
CSIR UGC NET Syllabus
CSIR UGC NET Chemical Sciences Syllabus
Inorganic Chemistry:
 Chemical periodicity
 Structure and bonding in homo and heteronuclear molecules, including shapes of molecules (VSEPR Theory).
 Concepts of acids and bases, HardSoft acid base concept, Nonaqueous solvents.
 Main group elements and their compounds: Allotropy, synthesis, structure and bonding, industrial importance of the compounds.
 Transition elements and coordination compounds: structure, bonding theories, spectral and magnetic properties, reaction mechanisms.
 Inner transition elements: spectral and magnetic properties, redox chemistry, analytical applications.
 Organometallic compounds: synthesis, bonding and structure, and reactivity. Organometallics in homogeneous catalysis.
 Cages and metal clusters.
 Analytical chemistry separation, spectroscopic, electro and thermoanalytical methods.
 Bioinorganic chemistry: photosystems, porphyrins, metalloenzymes, oxygen transport, electron transfer reactions; nitrogen fixation, metal complexes in medicine.
 Characterisation of inorganic compounds by IR, Raman, NMR, EPR, Mössbauer, UVvis, NQR, MS, electron spectroscopy and microscopic techniques.
 Nuclear chemistry: nuclear reactions, fission and fusion, radioanalytical techniques and activation analysis.
Physical Chemistry:
 Basic principles of quantum mechanics: Postulates; operator algebra; exactly solvable systems: particleinabox, harmonic oscillator and the hydrogen atom, including shapes of atomic orbitals; orbital and spin angular momenta; tunneling
 Approximate methods of quantum mechanics: Variational principle; perturbation theory up to second order in energy; applications
 Atomic structure and spectroscopy; term symbols; manyelectron systems and antisymmetry principle
 Chemical bonding in diatomics; elementary concepts of MO and VB theories; Huckel theory for conjugated πelectron systems.
 Chemical applications of group theory; symmetry elements; point groups; character tables; selection rules.
 Molecular spectroscopy: Rotational and vibrational spectra of diatomic molecules; electronic spectra; IR and Raman activities – selection rules; basic principles of magnetic resonance
 Chemical thermodynamics: Laws, state and path functions and their applications; thermodynamic description of various types of processes; Maxwell’s relations; spontaneity and equilibria; temperature and pressure dependence of thermodynamic quantities; etc
 Statistical thermodynamics: Boltzmann distribution; kinetic theory of gases; partition functions and their relation to thermodynamic quantities – calculations for model systems.
 Electrochemistry: Nernst equation, redox systems, electrochemical cells; DebyeHuckel theory; electrolytic conductance – Kohlrausch’s law and its applications; ionic equilibria; conductometric and potentiometric titrations
 Chemical kinetics: Empirical rate laws and temperature dependence; complex reactions; steady state approximation; determination of reaction mechanisms; collision and transition state theories of rate constants; unimolecular reactions; enzyme kinetics; salt effects; homogeneous catalysis; photochemical reactions.
 Colloids and surfaces: Stability and properties of colloids; isotherms and surface area; heterogeneous catalysis.
 Solid state: Crystal structures; Bragg’s law and applications; band structure of solids.
 Polymer chemistry: Molar masses; kinetics of polymerization.
 Data analysis: Mean and standard deviation; absolute and relative errors; linear regression; covariance and correlation coefficient.
Organic Chemistry:
 IUPAC nomenclature of organic molecules including regio and stereoisomers.
 Principles of stereochemistry: Configurational and conformational isomerism in acyclic and cyclic compounds; stereogenicity, stereoselectivity, enantioselectivity, diastereoselectivity and asymmetric induction.
 Aromaticity: Benzenoid and nonbenzenoid compounds – generation and reactions.
 Organic reactive intermediates: Generation, stability and reactivity of carbocations, carbanions, free radicals, carbenes, benzynes and nitrenes.
 Organic reaction mechanisms involving addition, elimination and substitution reactions with electrophilic, nucleophilic or radical species. Determination of reaction pathways.
 Common named reactions and rearrangements – applications in organic synthesis
 Organic transformations and reagents: Functional group interconversion including oxidations and reductions; common catalysts and reagents (organic, inorganic, organometallic and enzymatic). Chemo, regio and stereoselective transformations
 Concepts in organic synthesis: Retrosynthesis, disconnection, synthons, linear and convergent synthesis, umpolung of reactivity and protecting groups.
 Asymmetric synthesis: Chiral auxiliaries, methods of asymmetric induction – substrate, reagent and catalyst controlled reactions; determination of enantiomeric and diastereomeric excess; enantiodiscrimination. Resolution – optical and kinetic.
 Pericyclic reactions – electrocyclisation, cycloaddition, sigmatropic rearrangements and other related concerted reactions. Principles and applications of photochemical reactions in organic chemistry.
 Synthesis and reactivity of common heterocyclic compounds containing one or two heteroatoms (O, N, S).
 Chemistry of natural products: Carbohydrates, proteins and peptides, fatty acids, nucleic acids, terpenes, steroids and alkaloids. Biogenesis of terpenoids and alkaloids.
 Structure determination of organic compounds by IR, UVVis, 1H & 13C NMR and Mass spectroscopic techniques.
Interdisciplinary topics:
 Chemistry in nanoscience and technology
 Catalysis and green chemistry
 Medicinal chemistry
 Supramolecular chemistry
 Environmental chemistry
CSIR UGC NET Earth Science Syllabus
Paper I (PART B)
 The Earth and the Solar System
 Earth Materials, Surface Features and Processes
 Interior of the Earth, Deformation and Tectonics
 Oceans and Atmosphere
 Environmental Earth Sciences
Paper I (PART C)
 Mineralogy And Petrology
 Structural Geology And Geotectonics
 Paleontology And Its Applications
 Sedimentology And Stratigraphy
 Marine Geology And Paleoceanography
 Geochemistry
 Economic Geology
 Precambrian Geology And Crustal Evolution
 Quaternary Geology
 Remote Sensing and GIS
 Engineering Geology
 Mineral Exploration
 Hydrogeology
 Geomorphology
 Climatology
 Biogeography
 Environmental Geography etc
CSIR UGC NET Life Sciences Syllabus
 Molecules and their Interaction Relevant to Biology
 Cellular Organization
 Fundamental Processes
 Cell Communication and Cell Signaling
 Developmental Biology
 System Physiology – Plant
 System Physiology – Animal
 Inheritance Biology
 Diversity of Life Forms
 Ecological Principles
 Evolution and Behavior
 Applied Biology
 Methods in Biology
CSIR UGC NET
Mathematical Sciences Syllabus
Analysis: Elementary
set theory, finite, countable and uncountable sets, Real number system as a
complete ordered field, Archimedean property, supremum, infimum.
 Sequences and series, convergence, limsup, liminf.
 Bolzano Weierstrass theorem, Heine Borel theorem.
 Continuity, uniform continuity, differentiability, mean value theorem.
 Sequences and series of functions, uniform convergence.
 Riemann sums and Riemann integral, Improper Integrals.
 Monotonic functions, types of discontinuity, functions of bounded variation, Lebesgue measure, Lebesgue integral.
 Functions of several variables, directional derivative, partial derivative, derivative as a linear transformation, inverse and implicit function theorems.
 Metric spaces, compactness, connectedness. Normed linear Spaces. Spaces of continuous functions as examples.
 Linear Algebra: Vector spaces, subspaces, linear dependence, basis, dimension, algebra of linear transformations.
 Algebra of matrices, rank and determinant of matrices, linear equations.
 Eigenvalues and eigenvectors, CayleyHamilton theorem.
 Matrix representation of linear transformations. Change of basis, canonical forms, diagonal forms, triangular forms, Jordan forms. Inner product spaces, orthonormal basis.
 Quadratic forms, reduction and classification of quadratic forms
Complex Analysis: Algebra
of complex numbers, the complex plane, polynomials, power series,
transcendental functions such as exponential, trigonometric and hyperbolic
functions.
 Analytic functions, CauchyRiemann equations.
 Contour integral, Cauchy’s theorem, Cauchy’s integral formula, Liouville’s theorem, Maximum modulus principle, Schwarz lemma, Open mapping theorem.
 Taylor series, Laurent series, calculus of residues.
 Conformal mappings, Mobius transformations.
 Algebra: Permutations, combinations, pigeonhole principle, inclusionexclusion principle derangements.
 Fundamental theorem of arithmetic, divisibility in Z, congruences, Chinese Remainder Theorem,
 Euler’s Ø function, primitive roots.
 Groups, subgroups, normal subgroups, quotient groups, homomorphisms, cyclic groups, permutation groups, Cayley’s theorem, class equations, Sylow theorems.
 Rings, ideals, prime and maximal ideals, quotient rings, unique factorization domain, principal ideal domain, Euclidean domain.
 Polynomial rings and irreducibility criteria.
 Fields, finite fields, field extensions, Galois Theory.
 Topology: basis, dense sets, subspace and product topology, separation axioms, connectedness and compactness.
Ordinary Differential Equations
(ODEs):
 Existence and uniqueness of solutions of initial value problems for first order ordinary differential equations, singular solutions of first order ODEs, system of first order ODEs.
 General theory of homogenous and nonhomogeneous linear ODEs, variation of parameters, SturmLiouville boundary value problem, Green’s function. Partial Differential Equations (PDEs)
 Lagrange and Charpit methods for solving first order PDEs, Cauchy problem for first order PDEs.
 Classification of second order PDEs, General solution of higher order PDEs with constant coefficients, Method of separation of variables for Laplace, Heat and Wave equations.
Numerical Analysis:
Numerical solutions of algebraic equations, Method of
iteration and NewtonRaphson method, Rate of convergence, Solution of systems
of linear algebraic equations using Gauss elimination and GaussSeidel methods,
Finite differences, Lagrange, Hermite and spline interpolation, Numerical
differentiation and integration, Numerical solutions of ODEs using Picard,
Euler, modified Euler and RungeKutta methods.
Calculus of Variations:
Variation of a functional: EulerLagrange
equation, Necessary and sufficient conditions for extrema. Variational methods
for boundary value problems in ordinary and partial differential equations.
Linear Integral Equations: Linear
integral equation of the first and second kind of Fredholm and Volterra type,
Solutions with separable kernels. Characteristic numbers and Eigen functions,
resolvent kernel
Classical Mechanics: Generalized
coordinates, Lagrange’s equations, Hamilton’s canonical equations, Hamilton’s
principle and principle of least action, Twodimensional motion of rigid
bodies, Euler’s dynamical equations for the motion of a rigid body about an
axis, theory of small oscillations.
Check Here:
CSIR UGC NET General Aptitude Syllabus
 Logical Reasoning
 Graphical Analysis
 Analytical and Numerical Ability
 Quantitative Comparisons
 Series Formation
 Puzzles Etc.
CSIR UGC NET Exam Pattern
 The MCQ test paper of each subject shall carry a maximum of 200 marks.
 The exam shall be for duration of three hours.
 The question paper shall be divided in three parts
 Negative Marking for wrong answers
For Part A:
 Part 'A' shall be common to all subjects. This part shall be a test containing a maximum of 20 questions of General Aptitude.
 The candidates shall be required to answer any 15 questions of two marks each.
 The total marks allocated to this section shall be 30 out of 200.
For Part B:
 Part 'B' shall contain subjectrelated conventional MCQs.
 The total marks allocated to this section shall be 70 out of 200.
 The maximum number of questions to be attempted shall be in the range of 2035.
For Part C:
 Part 'C' shall contain higher value questions that may test the candidate's knowledge of scientific concepts and/or application of the scientific concepts.
 The questions shall be of analytical nature where a candidate is expected to apply the scientific knowledge to arrive at the solution to the given scientific problem.
 The total marks allocated to this section shall be 100 out of 200.
CSIR UGC NET Exam Syllabus PDF
Name of Subjects

UGC NET Syllabus PDF

Chemical Sciences


Earth Sciences


Life Sciences


Mathematical Sciences


Physical Sciences

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