tesTopper presents one of the most sought course for current assistant professor vacancy in Physics in Uttar Pradesh Degree Colleges including Government Degree College by UPPSC. This course will also hold 10 All UP Mock Tests on the same pattern as prescribed in the Exam Pattern.
Course Contents
Course Introduction
UPHESC Physics Exam 2021 is scheduled to help in October 2021 as announced by Board. This course will be an opportunity for uphesc assistant professor exam aspirants to prepare themselves for the uphesc physics exam 2021. This course will cover entire syllabus of the exam including 10 All UP Mock Tests (AUMT) so that every aspirant can check their understanding of the topics and get to know their weak points and prepare accordingly. Both recorded and live doubt clearing session will be held during the course and more than 400 hours of video lectures will be available.Course Features (UPHESC Physics Exam 2021)
1. Course starting date 20 July 15 October and will cover Entire Syllabus as per Exam Pattern. 2. 16 October 25 October, All UP Mock Test series along with Individual Section Tests as per Exam Pattern. 3. You can test and check the quality of our Test Series by attempting our First Mock Test Free. 4. Regular Lectures with Doubt clearing and Problemsolving sessions. 5. Lectures will be accessible only on our website. 6. Lectures will cover syllabus according to UPHESC both for written and Interview purposes. Theory and problemsolving techniques. 7. General Studies portion is also covered in lectures. 8. Total fees â‚¹ 15000/ including Mock Tests & GST, in case you want to reserve your seat, you can make advance payment of â‚¹ 1000/ & rest in 2 Equal Instalments. In case having any problem in making payment, contact support team. 9. Maximum seats for each batch 100, If no. of students increase, new batch will be formed.UPHESC Physics Exam 2021 Syllabus
UPHESC Assistant Professor Exam 2021 in physics will be based on following syllabus. To understand the other topics we should have detailed knowledge of mathematical methods in physics so, those who are weak in mathematics should revise and practice the section I of the course first and then should proceed with rest of the course. I. Mathematical Methods of Physics Dimensional analysis. Vector algebra and vector calculus. Linear algebra, matrices, CayleyHamilton Theorem. eigenvalue problems; Linear differential equations; special functions (Hermite, Bessel, Laguerre and Legendre); Recurrence relations. Fourier series, Fourier and Laplace transforms; Elements of complex analysis: Laurent seriespoles, residues and evaluation of integrals; Elementary ideas about thesors; Introductory group theory, SU(2), O(3); Elements of computational techniques: roots of functions, interpolation, extrapolation, integration by trapezoid and Simpsonâ€™s rule, solution of first order differential equations using RungeKutta method; Finite difference methods; Elementary probability theory, random variables, binomial, Poisson and normal distributions. II. Classical Mechanics Newtonâ€™s laws; Phase space dynamics, stability analysis; Centralforce motion; Twobody collisions, scattering in laboratory and centerofmass frames; Rigid body dynamics, moment of inertia tensor, Noninertial frames and pseudoforces; Variational principle, Lagrangian and Hamiltonian formalism 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 massâ€“energy equivalence. Twin Paradox, Hamilton â€“ Jacobi Theory. III. Electromagnetic Theory Electrostatics: Gaussâ€™s law and its applications; Laplace and Poisson equations, boundary value problems; Magnetostatics: BiotSavart 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, Fresnelâ€™s law, interference, coherence, and diffraction; Dispersion relations in plasma; Lorentz invariance of Maxwellâ€™s equations; Transmission lines and wave guides; Cavity Resonator, Dynamics of charged particles inÂ static and uniform electromagnetic fields; Radiation from moving charges, dipoles and retarded potentials Plasma. IV. Quantum Mechanics Waveparticle duality; Wave function in coordinate and momentum representations; Commutators and Heisenbergâ€™s uncertainty principle; Matrix representation; Diracâ€™s bra and ket notation; Schroedinger equation (timedependent and timeindependent); Eigenvalue problems such as particleinabox, 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, spinorbit coupling, fine structure; Timeindependent perturbation theory and Time dependent perturbation theory and Fermi's Golden Rule; Selection rules; Semiclassical theory of radiation; Elementary theory of scattering, phase shifts, partial waves, Born approximation; Identical particles, Pauliâ€™s exclusion principle, spinstatistics 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 grandcanonical ensembles and partition functions; Free Energy and connection with thermodynamic quantities; First and secondorder phase transition; Classical and quantum statistics,Â ideal Fermi and Bose gases; Principle of detailed balance; Blackbody radiation and Planckâ€™s distribution law; BoseEinstein condensation; Random walk and Brownian motion; Introduction to non equilibrium 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; Highfrequency 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. Oscillator, Amplifier, Modulation & demodulation, Switching time, High frequency devices. 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, chisquare test; Transducers (temperature, pressure/vacuum, magnetic field, vibration, optical, and particle detectors), measurement and control; Signal conditioning and recovery, impedance matching, amplification (Opamp based, instrumentation amp, feedback), filtering and noise reduction, shielding and grounding; Fourier transforms; lockin detector, boxcar integrator, modulation techniques. Application of experimental and analytical techniques. VIII. Atomic & Molecular Physics Quantum states of an electron in an atom; Electron spin; SternGerlach 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 couplings; Zeeman, Paschen Bach & Stark effect; Xray 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, UV and infrared spectrometry. 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 solids, Superconductivity: typeI and typeII superconductors. Josephson junctions; Defects and dislocations; Ordered phases of matter, translational and orientational order, kinds of liquid crystalline order; Conducting polymers; Quasicrystals, Quantum Hall effect. X. Nuclear and Particle Physics Basic nuclear properties: size, shape and charge distribution, spin and parity; Binding energy, semiempirical mass formula; Liquid drop model; Fission and fusion; Nature of the nuclear force, form of nucleonnucleon potential; Chargeindependence and chargesymmetry of nuclear forces; Isospin; Deuteron problem; Evidence of shell structure, singleparticle 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; GellMann Nishijima formula; C,P, and T invariance and application of symmetry arguments to particle reactions, parity nonconservation in weak interaction; Relativistic kinematics.More Information
Download Admit Card Suggested Books for UPHESC Physics Exam 2021tesTopper Guru
Taught By
Dr. Ekta Agarwal
Expert In
+8 Years in Teaching students of NET/JRF Physical Sciences
Professional Experience
Electrodynamic Theory, Classical Physics, Mathematical Physics
Courses Taught
37
Ratings
★★★★★ 4.7/5
Total Students
1273
Class Lectures

 Dimensional analysis Details Unlimited
 Vector algebra and vector calculus Details Unlimited
 Linear algebra Details Unlimited
 Matrices and Determinants Details Unlimited
 Cayley Hamilton Theorem Details Unlimited
 Eigenvalue problems Details Unlimited
 Linear differential equations Details Unlimited
 Special functions (Hermite, Bessel, Laguerre and Legendre) Details Unlimited
 Recurrence relations of Special functions Details Unlimited
 Fourier series Details Unlimited
 Fourier and Laplace transforms Details Unlimited
 Elements of complex analysis Details Unlimited
 Laurent seriespoles Details Unlimited
 Residues and evaluation of integrals Details Unlimited
 Elementary ideas about tensors Details Unlimited
 Introductory group theory, SU(2), O(3) Details Unlimited
 Elements of computational techniques Details Unlimited
 Roots of functions Details Unlimited
 Interpolation and extrapolation Details Unlimited
 Integration by trapezoid and Simpsonâ€™s rule Details Unlimited
 Solution of first order differential equations using RungeKutta method Details Unlimited
 Finite difference methods Details Unlimited
 Elementary probability theory Details Unlimited
 Random variables and binomial distribution Details Unlimited
 Poisson and normal distributions Details Unlimited
 UPHESC Physics 2021 Mock Test – 01 02:00:00

 Newtonâ€™s laws Details Unlimited
 Phase space dynamics and stability analysis Details Unlimited
 Centralforce motion Details Unlimited
 Twobody collisions Details Unlimited
 Scattering in laboratory and center of mass frames Details Unlimited
 Rigid body dynamics Details Unlimited
 Moment of inertia tensor Details Unlimited
 Noninertial frames and pseudoforces Details Unlimited
 Variational principle Details Unlimited
 Lagrangian and Hamiltonian formalism and equations of motion Details Unlimited
 Poisson brackets and canonical transformations Details Unlimited
 Symmetry Details Unlimited
 Invariance and conservation laws Details Unlimited
 Cyclic coordinates Details Unlimited
 Periodic motion Details Unlimited
 Small oscillations and normal modes Details Unlimited
 Special theory of relativity Details Unlimited
 Lorentz transformations Details Unlimited
 Relativistic kinematics and massâ€“energy equivalence Details Unlimited
 Twin Paradox Details Unlimited
 Hamilton â€“ Jacobi Theory Details Unlimited

 Electrostatics Details Unlimited
 Gaussâ€™s law and its applications Details Unlimited
 Laplace and Poisson equations Details Unlimited
 Boundary value problems Details Unlimited
 Magnetostatics Details Unlimited
 BiotSavart law and Ampere’s theorem Details Unlimited
 Electromagnetic induction Details Unlimited
 Maxwell’s equations in free space and linear isotropic media Details Unlimited
 Boundary conditions on fields at interfaces Details Unlimited
 Scalar and vector potentials Details Unlimited
 Gauge invariance Details Unlimited
 Electromagnetic waves in free space Details Unlimited
 Dielectrics and conductors Details Unlimited
 Reflection and refraction Details Unlimited
 Polarization Details Unlimited
 Fresnelâ€™s law Details Unlimited
 Interference, coherence and diffraction Details Unlimited
 Dispersion relations in plasma Details Unlimited
 Lorentz invariance of Maxwellâ€™s equations Details Unlimited
 Transmission lines and wave guides Details Unlimited
 Cavity Resonator Details Unlimited
 Dynamics of charged particles in static and uniform electromagnetic fields Details Unlimited
 Radiation from moving charges Details Unlimited
 Dipoles and Retarded potentials Plasma Details Unlimited
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