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CSIR UGC NET Syllabus 2022: Subject-wise Exam Pattern Download PDF

CSIR UGC NET Syllabus

The latest and updated CSIR UGC NET Syllabus & Exam Pattern are provided on this page. Here we have provided the direct links to Download CSIR NET Syllabus 2022 Syllabus PDF and CSIR UGC NET Exam Pattern 2022 for Chemical Sciences, Life Sciences, Physical Sciences, and other subjects.

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CSIR UGC NET 2022 Exam:

National Eligibility Test is conducted Council of Scientific & Industrial Research (CSIR) & University Grant Commission (UGC) for those individuals who want to make their career in the teaching field.

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CSIR UGC NET Syllabus

CSIR UGC NET 2022 Subjects

The subjects asked in CSIR UGC NET 2022 are tabulated as follows:

Subject Code Subjects of the Test
701 Chemical Sciences
702 Earth, Atmospheric, Ocean and Planetary Sciences
703 Life Sciences
704 Mathematical Sciences
705 Physical Sciences

CSIR UGC NET Syllabus 2022 – Chemical Sciences

Physical Chemistry:

  • Basic principles and applications of quantum mechanics – hydrogen atom, angular momentum
  • Variational and perturbational methods
  • Basics of atomic structure, electronic configuration, shapes of orbitals, hydrogen atom spectra
  • Theoretical treatment of atomic structures and chemical bonding
  • Chemical applications of group theory
  • Basic principles and application of spectroscopy – rotational, vibrational, electronic, Raman, ESR, NMR
  • Chemical thermodynamics
  • Phase equilibria
  • Statistical thermodynamics
  • Chemical equilibria
  • Electrochemistry – Nernst equation, electrode kinetics, electrical double layer, Debye-Hückel theory
  • Chemical kinetics – empirical rate laws, Arrhenius equation, theories of reaction rates, determination of reaction mechanisms, experimental techniques for fast reactions
  • Concepts of catalysis
  • Polymer chemistry Molecular weights and their determinations Kinetics of chain polymerization
  • Solids – structural classification of binary and ternary compounds, diffraction techniques, bonding, thermal, electrical and magnetic properties
  • Collids and surface phenomena
  • Data analysis

Inorganic Chemistry:

  • Chemical periodicity
  • Structure and bonding in homo- and heteronuclear molecules, including shapes of molecules
  • Concepts of acids and bases
  • Chemistry of the main group elements and their compounds. Allotropy, synthesis, bonding and structure
  • Chemistry of transition elements and coordination compounds – bonding theories, spectral and magnetic properties, reaction mechanisms
  • Inner transition elements – spectral and magnetic properties, analytical applications
  • Organometallic compounds – synthesis, bonding and structure, and reactivity Organometallics in homogenous catalysis
  • Cages and metal clusters
  • Analytical chemistry- separation techniques, Spectroscopic electro- and thermoanalytical methods
  • Bioinorganic chemistry – photosystems, porphyrines, metalloenzymes, oxygen transport, electron- transfer reactions, nitrogen fixation
  • Physical characterisation of inorganic compounds by IR, Raman, NMR, EPR, Mössbauer, UV-, NQR, MS, electron spectroscopy and microscopic techniques
  • Nuclear chemistry – nuclear reactions, fission and fusion, radio-analytical techniques and activation analysis

Organic Chemistry:

  • IUPAC nomenclature of organic compounds
  • Principles of stereochemistry, conformational analysis, isomerism and chirality
  • Reactive intermediates and organic reaction mechanisms
  • Concepts of aromaticity
  • Pericyclic reactions
  • Named reactions
  • Transformations and rearrangements
  • Principles and applications of organic photochemistry, Free radical reactions
  • Reactions involving nucleophotic carbon intermediates
  • Oxidation and reduction of functional groups
  • Common reagents (organic, inorganic and organometallic) in organic synthesis
  • Chemistry of natural products such as steroids, alkaloids, terpenes, peptides, carbohydrates, nucleic acids and lipids
  • Selective organic transformations – chemoselectivity, regioselectivity, stereoselectivity, enantioselectivity, Protecting groups
  • Chemistry of aromatic and aliphatic heterocyclic compounds
  • Physical characterisation of organic compounds by IR, UV-, MS, and NMR

Interdisciplinary topics:

  • Chemistry in nanoscience and technology
  • Catalysis and green chemistry
  • Medicinal chemistry
  • Supramolecular chemistry
  • Environmental chemistry

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CSIR UGC NET 2022 Syllabus – Life Sciences

Molecules And Their Interaction Relevant To Biology:

  • Structure of atoms, molecules and chemical bonds
  • Composition, structure and function of biomolecules (carbohydrates, lipids, proteins, nucleic acids and vitamins)
  • Stablizing interactions (Van der Waals, electrostatic, hydrogen bonding, hydrophobic interaction, etc)
  • Principles of biophysical chemistry (pH, buffer, reaction kinetics, thermodynamics, colligative properties)
  • Bioenergetics, glycolysis, oxidative phosphorylation, coupled reaction, group transfer, biological energy transducers
  • Principles of catalysis, enzymes and enzyme kinetics, enzyme regulation, mechanism of enzyme catalysis, isozymes
  • Conformation of proteins (Ramachandran plot, secondary, tertiary and quaternary structure; domains; motif and folds)
  • Conformation of nucleic acids (A-, B-, Z-,DNA), t-RNA, micro-RNA)
  • Stability of protein and nucleic acid structures
  • Metabolism of carbohydrates, lipids, amino acids, nucleotides and vitamins

Cellular Organization:

  • Membrane structure and function: Structure of model membrane, lipid bilayer and membrane protein diffusion, osmosis, ion channels, active transport, ion pumps, mechanism of sorting and regulation of intracellular transport, electrical properties of membranes
  • Structural organization and function of intracellular organelles: Cell wall, nucleus, mitochondria, Golgi bodies, lysosomes, endoplasmic reticulum, peroxisomes, plastids, vacuoles, chloroplast, structure & function of cytoskeleton and its role in motility.
  • Organization of genes and chromosomes: Operon, interrupted genes, gene families, structure of chromatin and chromosomes, unique and repetitive DNA, heterochromatin, euchromatin, transposons.
  • Cell division and cell cycle: Mitosis and meiosis, their regulation, steps in cell cycle, and control of cell cycle.
  • Microbial Physiology: Growth, yield, and characteristics, strategies of cell division, stress response

Fundamental Processes:

  • DNA replication, repair, and recombination: Unit of replication, enzymes involved, replication origin and replication fork, fidelity of replication, extrachromosomal replicons, DNA damage and repair mechanisms
  • RNA synthesis and processing: Transcription factors and machinery, formation of initiation complex, transcription activators and repressors, RNA polymerases, capping, elongation and termination, RNA processing, RNA editing, splicing, polyadenylation, structure, and function of different types of RNA, RNA transport.
  • Protein synthesis and processing: Ribosome, formation of initiation complex, initiation factors and their regulation, elongation and elongation factors, termination, genetic code, aminoacylation of tRNA, tRNA-identity, aminoacyl tRNA synthetase, translational proof-reading, translational inhibitors, post-translational modification of proteins.
  • Control of gene expression at transcription and translation level: Regulation of phages, viruses, prokaryotic and eukaryotic gene expression, role of chromatin in regulating gene expression and gene silencing

Cell Communication And Cell Signaling:

  • Host-parasite interaction: Recognition and entry processes of different pathogens like bacteria, viruses into animal and plant host cells, alteration of host cell behavior by pathogens, virus-induced cell transformation, pathogen-induced diseases in animals and plants, cell-cell fusion in both normal and abnormal cells.
  • Cell signaling: Hormones and their receptors, cell surface receptor, signaling through G-protein coupled receptors, signal transduction pathways, second messengers, regulation of signaling pathways, bacterial and plant two-component signaling systems, bacterial chemotaxis and quorum sensing
  • Cellular communication: Regulation of hematopoiesis, general principles of cell communication, cell adhesion and roles of different adhesion molecules, gap junctions, extracellular matrix, integrins, neurotransmission and its regulation
  • Cancer: Genetic rearrangements in progenitor cells, oncogenes, tumor suppressor genes, cancer and the cell cycle, virus-induced cancer, metastasis, interaction of cancer cells with normal cells, apoptosis, therapeutic interventions of uncontrolled cell growth.

Get Complete Detailed: UGC NET Syllabus

CSIR NET Syllabus 2022 – Mathematical Sciences

Unit– 1 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.
  • 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, Cayley-Hamilton 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.

Unit– 2 Syllabus

Complex Analysis:

  • Algebra of complex numbers, the complex plane, polynomials, Power series, transcendental functions such as exponential, trigonometric and hyperbolic functions.
  • Analytic functions, Cauchy-Riemann 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, pigeon-hole principle, inclusion-exclusion 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.

CSIR UGC NET Syllabus 2022 – Physical Sciences

I.Mathematical Methods of Physics:

  • Dimensional analysis
  • Vector algebra and vector calculus
  • Linear algebra, matrices
  • Cayley Hamilton theorem
  • eigenvalue problems
  • Linear differential equations
  • Special functions (Hermite, Bessel, Laguerre and Legendre)
  • Fourier series,
  • Fourier and Laplace transforms
  • Elements of complex analysis
  • Laurent series-poles
  • residues and evaluation of integrals
  • Elementary ideas about tensors
  • Introductory group theory, SU(2), O(3)
  • Elements of computational techniques
  • roots of functions
  • interpolation, extrapolation
  • integration by trapezoid and Simpson’s rule
  • solution of first-order differential equations using the Runge-Kutta method
  • Finite difference methods
  • Elementary probability theory
  • random variables
  • binomial
  • Poisson and normal distributions

II.Classical Mechanics Newton’s laws:

  • Phase space dynamics, stability analysis
  • Central-force motion
  • Two-body collisions
  • scattering in laboratory and center-of-mass frames
  • Rigid body dynamics
  • moment of inertia tensor
  • non-inertial frames and pseudo forces
  • Variational principle
  • Lagrangian and Hamiltonian formalisms and equations of motion
  • Poisson brackets and canonical transformations
  • Symmetry
  • invariance and conservation laws
  • cyclic coordinates
  • Periodic motion
  • small oscillations and normal modes
  • Special theory of relativity
  • Lorentz transformations
  • relativistic kinematics and
  • mass–energy equivalence.

III. Electromagnetic Theory Electrostatics:

  • Gauss’ Law and its applications;
  • Laplace and Poisson equations, boundary value problems; Magnetostatics
  • Biot-Savart law, Ampere’s theorem, electromagnetic induction
  • Maxwell’s equations in free space and linear isotropic media
  • boundary conditions on fields at interfaces
  • Scalar and vector potentials
  • Gauge invariance
  • Electromagnetic waves in free space, dielectrics, and conductors
  • Reflection and refraction, polarization, Fresnel’s Law, interference, coherence, and diffraction
  • Dispersion relations in plasma
  • Lorentz invariance of Maxwell’s equations
  • Transmission lines and wave guides
  • Dynamics of charged particles in static and uniform electromagnetic fields
  • Radiation from moving charges, dipoles and retarded potentials.

IV.Quantum Mechanics Wave-particle duality:

  • Wave functions in coordinate and momentum representations
  • Commutators and Heisenberg’s uncertainty principle
  • Matrix representation
  • Dirac’s bra and ket notation
  • Schroedinger equation (time-dependent and time-independent)
  • Eigenvalue problems such as particle-in-a-box, harmonic oscillator, etc.
  • Tunneling through a barrier
  • Motion in a central potential
  • Orbital angular momentum, Angular momentum algebra, spin
  • Addition of angular momenta
  • Hydrogen atom, spin-orbit coupling, fine structure; Timeindependent perturbation theory and applications
  • Variational method
  • WKB approximation
  • Time dependent perturbation theory and Fermi’s Golden Rule
  • Selection rules
  • Semi-classical theory of radiation
  • Elementary theory of scattering, phase shifts, partial waves, Born approximation
  • Identical particles, Pauli’s exclusion principle, spin-statistics connection
  • Relativistic quantum mechanics
  • Klein Gordon and Dirac equations.

V.Thermodynamic and Statistical Physics Laws of thermodynamics and their consequences:

  • Thermodynamic potentials, Maxwell relations
  • Chemical potential
  • phase equilibria
  • Phase space, micro- and macrostates
  • Microcanonical, canonical and grand-canonical ensembles and partition functions
  • Free Energy and connection with thermodynamic quantities; First- and second-order phase transitions
  • Classical and quantum statistics, ideal Fermi and Bose gases
  • Principle of detailed balance
  • Blackbody radiation and Planck’s distribution law
  • Bose-Einstein condensation
  • Random walk and Brownian motion
  • Introduction to nonequilibrium processes
  • Diffusion equation.

VI.Electronics:

  • Semiconductor device physics
  • including diodes
  • junctions
  • transistors
  • Field-effect devices
  • homo and heterojunction devices,
  • device structure device characteristics, frequency dependence and applications
  • Optoelectronic devices, including solar cells, photodetectors, and LEDs
  • High-frequency devices, including generators and detectors
  • Operational amplifiers and their applications
  • Digital techniques and applications (registers, counters, comparators and similar circuits)
  • A/D and D/A converters
  • Microprocessor and microcontroller basics.

VII. Experimental Techniques and data analysis:

  • Data interpretation and analysis
  • Precision and accuracy
  • error analysis
  • propagation of errors
  • least squares fitting
  • linear and nonlinear curve fitting
  • chi-square test
  • Transducers (temperature, pressure/vacuum, magnetic field, vibration, optical, and particle detectors), measurement and control
  • Signal conditioning and recovery, impedance matching,
  • amplification (Op-amp based, instrumentation amp, feedback),
  • filtering and noise reduction, shielding and grounding
  • Fourier transforms
  • lock-in detector, box-car integrator, modulation techniques.

VIII. Atomic & Molecular Physics:

  • Quantum states of an electron in an atom
  • Electron spin
  • Stern-Gerlach experiment
  • Spectrum of Hydrogen, helium and alkali atoms
  • Relativistic corrections for energy levels of hydrogen
  • Hyperfine structure and isotopic shift width of spectral lines
  • LS & JJ coupling; Zeeman, Paschen Back & Stark effect
  • X-ray spectroscopy
  • Electron spin resonance, Nuclear magnetic resonance, chemical shift
  • Rotational, vibrational, electronic, and Raman spectra of diatomic molecules
  • Frank – Condon principle and selection rules
  • Spontaneous and stimulated emission, Einstein A & B coefficients; Lasers,
  • optical pumping, population inversion, rate equation
  • Modes of resonators and coherence length.

IX.Condensed Matter Physics:

  • Bravais lattices
  • Reciprocal lattice, diffraction and the structure factor
  • Bonding of solids; Elastic properties, phonons, lattice specific heat
  • Free electron theory and electronic specific heat
  • Response and relaxation phenomena
  • Drude model of electrical and thermal conductivity
  • Hall effect and thermoelectric power
  • Diamagnetism, paramagnetism, and ferromagnetism
  • Electron motion in a periodic potential, band theory of metals, insulators and semiconductors
  • Superconductivity, type – I and type – II superconductors, Josephson junctions
  • Defects and dislocations
  • Ordered phases of matter, translational and orientational order, kinds of liquid crystalline order
  • Conducting polymers

X.Nuclear and Particle Physics:

  • Basic nuclear properties
  • size, shape, charge distribution, spin and parity
  • Binding energy, semi-empirical mass formula
  • Liquid drop model; Fission and fusion
  • Nature of the nuclear force, form of nucleon-nucleon potential
  • Charge-independence and charge-symmetry of nuclear forces
  • Isospin
  • Deuteron problem
  • Evidence of shell structure, single- particle shell model, its validity and limitations
  • Rotational spectra
  • Elementary ideas of alpha
  • beta and gamma decays and their selection rules
  • Nuclear reactions, reaction mechanisms, compound nuclei and direct reactions
  • Classification of fundamental forces
  • Elementary particles (quarks, baryons, mesons, leptons)
  • Spin and parity assignments
  • isospin, strangeness; Gell-MannNishijima formula
  • C, P, and T invariance and applications of symmetry arguments to particle reactions
  • parity non-conservation in weak interaction
  • Relativistic kinematics

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Chemical Sciences Scheme Of Examination Syllabus
Earth Sciences Scheme Of Examination Syllabus
Life Sciences Scheme Of Examination Syllabus
Mathematical Sciences Scheme Of Examination Syllabus
Physical Sciences Scheme Of Examination Syllabus

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CSIR UGC NET Exam Pattern 2022

CSIR NET 2022 Exam Pattern:

Features Description
Format of exam Multiple Choice Questions
Mode of CSIR UGC NET exam Pen and Paper mode
Session Timings Forenoon Session – 9 AM to 12 PM
Afternoon Session – 2 PM to 5 PM
Total marks 200
Exam Duration 3 hours
List of Subjects Life Sciences Earth, Atmospheric, Ocean and Planetary Sciences, Mathematical Sciences, Chemical Sciences and Physical Sciences

CSIR NET Exam Pattern for Physical Science:

Sections No. of Ques. Given No. of Ques. to be Attempted Marks
PART-A 20 15 30
PART-B 25 20 70
PART-C 30 20 100
Total Marks 200

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CSIR NET Exam Pattern for Chemical Science:

Sections No. of Ques. Given No. of Ques. to be Attempted Marks
PART-A 20 15 30
PART-B 40 35 70
PART-C 60 25 100
Total Marks 200

CSIR NET 2022 Exam Pattern for Life Science:

Sections No. of Ques. Given No. of Ques. to be Attempted Marks
PART-A 20 15 30
PART-B 50 35 70
PART-C 75 25 100
Total Marks 200

NET CSIR Exam Pattern for Mathematical Science:

Sections No. of Ques. Given No. of Ques. to be Attempted Marks
PART-A 20 15 30
PART-B 40 20 75
PART-C 60 20 95
Total Marks 200

CSIR NET Earth Science Exam Pattern 2022:

Sections No. of Ques. Given No. of Ques. to be Attempted Marks
PART-A 20 15 30
PART-B 50 35 70
PART-C 80 25 100
Total Marks 200

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