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October 10, 2024

Kerala SET Physics Exam Pattern 2025, A Comprehensive Guide and Online Coaching

Table of Contents

Kerala SET Physics 2025: Exam

Kerala SET Physics 2025: Exam Pattern

Kerala SET Physics 2025: Syllabus

LBS SET Physics Exam: Previous Questions

Overview

Kerala Set exam notification was released by LBS Centre for Science and Technology. This crucial examination grands qualitative certification for candidates who have sufficient qualification in any of the 36 subjects listed in the official prospectus. The Kerala SET certification is a decisive qualification for candidates aspiring to become Higher Secondary School Teachers in Kerala. Physics is one among the most demanded subjects in Higher Secondary Schools. It is important that the candidates preparing for the upcoming Kerala SET Physics exam is aware about the nature, important dates and syllabus.

Kerala SET Physics 2025: Exam

Kerala SET Physics exam is an unavoidable event for those candidates who are aiming a Physics teaching job in Higher Secondary Education. The certification is compulsory for those who are applying for Kerala PSC HSST Physics examination. LBS Centre for Science and Technology conducts the Kerala SET exam twice every year. As per the official notification Kerala SET exam 2025 will be conducted in the month of January.

Kerala SET Physics Notification

The Kerala SET notification was released in September 2024. Candidates shall read or download the detailed Kerala SET notification from the official website of LBS centre.

Kerala SET Physics: How to Apply

Candidates applying for Kerala SET Physics exam must follow the step by step instructions in the official site.

Step1: Start the registration by providing your mobile number. Same mobile number cannot be used to register multiple candidates. There will be an OTP verification for the mobile number.

Step 2: fill the registration form with all relevant details such as subject of specialization, community, educational qualification etc.

Step 3: Upload your photo with a maximum 30 KB size. Height = 200 pixels, width = 150 pixels.

Step 4: Now candidates can pay the LBS SET exam fees through online. Make sure the payment is completed successfully.

Step5: Print the application form you have submitted online. This is for the future reference and other relaxations such as availing scribe facility, relaxation in marks for differently challenged candidates, etc.

Kerala SET Important Dates

The candidates applying for Kerala SET Physics exam must go through the following important dates in the timeline of the upcoming exam.

LBS SET Exam Important Dates
LBS SET Physics Exam Date	Yet to be released
LBS SET Physics Online Registration Start Date	September 25, 2024
LBS SET Physics Online Registration Closing Date	October 20, 2024
LBS SET Physics Last Date for Online Payment	October 22, 2024
LBS SET Physics Editing of Application	23 - 25 October, 2024
LBS SET Physics Admission Ticket Available Date	Yet to be released

Kerala SET Physics 2025: Exam Pattern

Kerala SET exam 2025 consists of two papers. Paper I or General Paper is the common paper for all candidates appearing for the SET certification of various subjects. Both Paper I and II of LBS SET has separate syllabus. candidates preparing for the Kerala SET exam must consider the syllabuses of both the paper while designing a preparation strategy. Each paper comprises 120 questions each. The examination for each paper is conducted separately with interval in between. Preparation is the crucial part in cracking Kerala SET exam 2025.

Kerala SET Physics Preparation

In order to clear the Kerala SET exam candidates, need a comprehensive preparation strategy for Paper I and Paper II. Subjects must plan according to the importance. Candidates need an insightful analysis of the Kerala SET Physics previous question analysis.

The best SET coaching centre in Kerala such as Competitive Cracker provide online courses for Physics. The latest features of the SET Astra courses ensure a better preparation for the exam. The best facilities such of the course such as “hello student” helps the candidates to stay motivated throughout the coaching program.

Kerala SET Physics 2025: Syllabus

LBS SET Physics exam is conducted on a well-defined syllabus. Each syllabus topic for this LBS Paper II exam is designed to test the proficiency in each topic. The topics being tested in the LBS SET Physics Exam 2025 are:

LBS SET Physics Syllabus Overview
Unit I
Mathematical Physics	Classical Mechanics
Unit II
Quantum Mechanics	Statistical Mechanics
Unit III
Electromagnetic Theory	Atomic and Molecular Physics
Unit IV	Unit V
Nuclear and Particle Physics	Condensed Matter Physics
Unit VI
Electronics

Detailed Syllabus

All candidates preparing for the upcoming Kerala SET exam must go through the detailed LBS SET Physics syllabus 2025. The syllabus is divided into 6 units and subdivided into modules. Each module consists of an important topic. Find the detailed syllabus for the upcoming LBS SET Physics exam below.

Unit I

Module 1. Mathematical physics

Dimensional analysis, Vector algebra and vector calculus, Linear algebra, matrices, Cayley- Hamilton Theorem, Eigen values and eigen vectors. Linear differential equations of first and second order. Fourierseries, Fourier and Laplace transforms. Elementary complex analysis, analytic functions; Taylor & Laurent series; poles, residues and evaluation of integrals. Special functions (Hermite, Bessel, Laguerre and Legendre). Elementary probability theory, random variables, binomial, Poisson and normal distributions. Central limit theorem.

Module 2. Classical Mechanics

Newton’s laws, Dynamical systems, Phase space dynamics, stability analysis. Central force motions. Two body Collisionsscattering in laboratory and Centre of mass frames. Rigid body dynamics – moment of inertia tensor. Non–inertial frames and pseudoforces. Variational principle. Generalized coordinates. Lagrangian and Hamiltonian formalism and equations of motion. Conservation laws and cyclic coordinates. Periodic motion: small oscillations, normal modes. Special theory of relativity- Lorentz transformations, relativistic kinematics and mass-energy equivalence, Poisson brackets and canonical transformations. Hamiltonian-Jacobi theory.

Unit II

Module 1. Quantum Mechanics

Wave-particle duality. Schrodinger equation (time dependent and time- independent). Eigenvalue problems (particle in a box, harmonic oscillator). Tunnelling through a barrier. Wave-function in coordinate and momentum representations. Commutators and Heisenberg uncertainty principle. Dirac notation for state vectors. Motion in certain potential: orbital angular momentum, angular momentum algebra, spin, addition of angular momenta. Hydrogen atom. Stern-Gerlach experiment. Time-independent perturbation theory and applications. Variational method. Time dependent perturbation theory and Fermi’s golden rule, selection rules. Identical particles, Paulis exclusion principle, spin-statistics connection, WKB approximation. Elementary theory of scattering: phase shifts, partial waves, Born approximation.

Module 2. Statistical Mechanics

Thermodynamic potentials, Maxwell relations, chemical potential, phase equilibria. Phase space, micro and macro states. Micro- canonical, canonical and grand-canonical ensembles and partition functions. Free energy and its connection with thermodynamic quantities. Classical and quantum statistics. Ideal Bose and Fermi gases. Blackbody radiation and Planck’s distribution law, Bose- Einstein condensation.

Unit III

Module 1. Electromagnetic Theory

Electrostatics: Gauss’s law and its applications, Laplace and Poissons equations, boundary value problems. Magnetostatics: Biot- Savart law, Ampere’s theorem. Electromagnetic induction. Maxwell’s equations in free space and linear isotopic media; boundary conditions on the 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. Dynamics of charged particles in static and uniform electromagnetic fields, Dispersion relations in plasma. Lorentz invariance of Maxwell’s equations. Transmission lines and wave guides. Radiation – from moving charges and dipoles and retarded potentials.

Module 2. Atomic and Molecular Physics

Quantum states of an electron in an atom. Electron spin. Spectrum of helium and alkali atom. Relativistic corrections for energy levels of hydrogen atom, hyperfine structure and isotopic shift, width of spectrum lines, LS & JJ couplings. Zeeman, Paschen –Bach & Stark effects. Electron spin resonance. Nuclear magnetic resonance, chemical shift. Frank-Condon principle. Born-Oppenheimer approximation. Electronic, Rotational, Vibrational and Raman spectra of diatomic molecules, selection rules. Lasers: spontaneous and stimulated emission, Einstein A & B coefficients. Optical pumping, population inversion, rate equation. Modes of resonators and coherence length.

Unit IV

Nuclear and Particle Physics

Basic nuclear properties: size, shape and charge distribution, spin and parity. Binding energy, semi-empirical mass formula, liquid drop model. Nature of the nuclear force, form of nucleon-nucleon potential, charge independence and charge- symmetry of nuclear forces. 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. Fission and Fusion. Nuclear reactions, reaction mechanisms, compound nuclei and direct reactions. Classification of fundamental forces. Elementary particles and their quantum numbers (charge, spin, parity, isospin, stangeness, etc.). Gell-Mann–Nishijima formula. Quark model, baryons and mesons. C, P and T invariance. Application of symmetry arguments to particle reactions. Parity non- conservation in weak interaction. Relativistic kinematics.

Unit V

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. Electron motion in a periodic potential, band theory of solids: metals, insulators and semiconductors, First and second order phase transitions. Diamagnetism, Paramagnetism and ferromagnetism, Superconductivity: type1 and type 2 superconductors, Josephson junctions. Superfluidity. Defects and dislocations Ordered phases of matter: translational and orientational order, kinds of liquid crystalline order. Quasi crystals.

Unit VI

Electronics

Semiconductor devices (diodes, junctions, transistors, field effect devices, homo and hetero- junction devices). Transistor amplifiers and oscillators, device structure, device characteristics, frequency dependence and applications. Opto-electronic devices (solar cells, photo-detectors, LEDs). 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. Data interpretation and analysis. Precision and accuracy. Error analysis, propagation of errors. Least squares fitting.

LBS SET Physics Exam: Previous Questions

The diagonal elements of which matrix must be pure imaginary numbers or zero?
1. Symmetric
2. Skew Symmetric
3. Hermitian
4. Skew Hermitian
The path followed by a particle in sliding from one point to another in the absence of friction in the shortest distance is a -----
1. Cycloid
2. Sigmoid
3. Sphere
4. Catenary of revolution
The existence of zero point energy for a linear harmonic oscillator is a consequence of -----
1. Pauli’s exclusion principle
2. Uncertainty principle
3. Matter waves
4. Special theory of relativity
In case of Bose-Einstein Condensation, number of particles -----
1. Increases in lower energy levels at low temperatures and high pressures.
2. Decreases in lower energy levels of low temperatures and high pressures.
3. Increases in lower energy levels at high temperatures and low pressure
4. Decreases in lower energy levels at high temperatures and low pressures
The displacement current arises due to -----
1. Positive charges only
2. Negative charges only
3. Both positive and negative charges
4. Time varying electric field
In a very strong magnetic field, the splitting of a spectral line is normal. This effect is called ----- Effect.
1. Zeeman
2. Raman
3. Paschen-Back
4. Stark
According to the Shell model of the nucleus, which of the following is incorrect?
1. Magic numbers exist
2. Nucleons interact with their nearest neighbours only
3. Nucleons in a nucleus interact with a general force field
4. Large electronic quadrupole moment exists for certain nuclei
NaCl crystals appear yellow due to -----
1. Schottky defect
2. Frenkel defect
3. Interstitials
4. F-centres
RC oscillators are usually used in ----- frequency range.
1. Audio
2. Radio
3. Video
4. Ultrahigh
If the generalized coordinate is angle, the corresponding generalized force has the dimension of :
1. Force
2. Torque
3. Energy
4. Momentum
The potential energy of an electron in hydrogen atom is ---- its kinetic energy.
1. Half of
2. Twice
3. Equal to
4. Thrice
The number of Bravias lattices that can exist is:
1. 17
2. 14
3. 32
4. 23