B.Sc. in Physics (PHM-361T)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 APPLY ANALYZE Analyse Bose Einstein and Fermi Dirac Distributions: Symmetry of wave functions, Calculate the results for Partition function for Diatomic Molecules. CO2 UNDERSTAND APPLY ANALYZE Strong understanding of how to model, classify, and solve key partial differential equations (PDEs) that describe important physical phenomena. Apply the method of separation of variables to solve common PDEs like the heat, wave, and Laplace Equations. Develop the ability to apply, PDEs as mathematical models for physical and engineering problems. CO3 APPLY ANALYZE To evaluate the eigenvalue problems of the quantum harmonic oscillator and interpret the role of operators, commutation relations, and spherical harmonics that is connected with the most important fundamental concept of angular momentum in quantum mechanics. CO4 UNDERSTAND APPLY ANALYZE Understanding the detailed behavior of plasma in magnetic field. Also analyze the production and propagation of different types of waves in plasma. The fundamental Boltzmann equation is used in plasma to study some basic nonlinear phenomena like Landau damping and Plasma Sheath.
B.Sc. in Physics (PHSEC-356)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 UNDERSTAND APPLY ANALYZE Describe the basic structure, composition, and visible features ofthe Sun. Explain the layers of the solar atmosphere and analyse phenomena like the solar corona and solar temperature distribution. CO2 APPLY ANALYZE Interpret the causes and effects of solar activity, including sunspot formation and the solar cycle. Identify the components of cosmic rays and explain the origin, energy spectrum, and nature of primary and secondary cosmic rays. Discuss the astrophysical significance of cosmic rays and describe mechanisms of their confinement and propagation
B.Sc. in Physics (PHM-355P)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 REMEMBER UNDERSTAND Set up the instruments as per the instructions, Connect the circuit as given in the circuit diagram. CO2 UNDERSTAND APPLY Develop measurements techniques, record observations, use the given formula, do calculations and draw your conclusion from the result.. CO3 EVALUATE Find uncertainty involved in the observations CO4 ANALYSE Analyse the observations for scientific inference
B.Sc. in Physics (PHM-354T)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 REMEMBER UNDERSTAND APPLY Remember the concept of radioactive decay, half life and mean life of radio active element. Understand the decay and growth of radioactive element. Also understand different equilibrium. Evaluate the estimated value of age of the earth by using lead method and carbon dating method. CO2 REMEMBER UNDERSTAND EVALUATE APPLICATION Remember the construction and basic working of transistor and zener diode. Understand the different configuration of transistor and their characteristics.. Evaluate different parameters like collector cut off current, leakage current etc. Also understand regulation process executed by zener diode working of tunnel diode. Also calculate different parameters related to regulation process which helps to design any regulator circuit. CO3 UNDERSTAND APPLY Basic wave concept of light is studied using the diffraction phenomenon. Apply the knowledge to understand the resolutions of some basic optical instruments CO4 UNDERSTAND APPLY ANALYSE Develop a conceptual understanding of the Time dependent and Timeindependent Schrodinger equations, their physical significance, and their application to basic quantum systems such as free particles, particles in a box, and barrier potential. Analyze and interpret the general wave equation, the physical meaning of the wave function, and probability current density. Students will discuss non-normalizable wave functions and the significance ofbox normalization. Solve the Schrodinger equation for standard potentials (infinite square well, particle in a box, and barrier potential), understand quantization of energy levels, and explain the concept of stationary states and their time evolution. Understand and articulate the general formalism of wave mechanics including the use of operator algebra, fundamental postulates, adjointness and self-adjointness of operators, eigenvalue problems (including degeneracy, observables, and normalization), and the use of Dirac delta functions and closure relations in quantum mechanic. Describe and employ critical tools such as the probability interpretation for [N ]-particle systems, the completeness of eigenfunctions, and normalization conditions necessary for quantum descriptions
B.Sc. in Physics (PHM-352T)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 APPLY ANALYZE EVALUATE Analyze elastic strains. Calculate elastic constants and explain wave propagation in crystalline solids. Evaluate the free electron model, calculate Fermi energy and density of states, Explain thermal and electrical conductivities in metals CO2 APPLY ANALYZE Apply Maxwell equation to understand and analyze the electromagnetic waves propagation in different mediums. Apply the concept to understand the skin depth. Apply the concepts of electrostatics for analyzing the boundary value problems and method of images CO3 APPLY ANALYZE EVALUATE Apply theory of radioactive decay of unstable nuclei and understand the properties and characteristics of a, ẞ and Y decay. Also evaluate the possible energy levels during this decay & disintegration energy and study the hyperfine structure of element. CO4 UNDERSTAND APPLY Remember the basic working characteristics of active devices like transistor. Understand the amplification process and analyse the characteristics of transistor amplification. By applying these characteristics, calculation of different parameters related with amplification process can be done.
B.Sc. in Physics (PHM-351T)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 APPLY ANALYZE EVALUATE Clear understanding of cause of rotational and vibrational of diatomic molecules and theoretical understanding on the basis of quantum theory is developed in detail. More realistic picture of rotational – vibrational spectra also becomes clear. Sufficient numbers of problems of rotational spectroscopy and rotational vibrational spectroscopy are also covered. CO2 APPLY ANALYZE Clear understanding of cause of Raman spectra, theoretical understanding of classical Raman theory and quantum theory is developed. Classification of Molecular Electronic States gives insight of understanding of molecular orbitals. Sufficient numbers of problems on the topics are also covered. CO3 APPLY ANALYZE EVALUATE Revise the knowledge of the Newtonian mechanics and Learn to define generalised coordinates, generalised velocities, generalised force and write Lagrangian for mechanical system in terms of generalised coordinates. Apply D’Alembert’s principle to obtain Lagrange’s equations, describe Lagrangian formulations, the ability to formulate Lagrangian dynamics to solve complex problems, apply Lagrange equations to analyse mechanical systems, understand the relationship between symmetries and conservation laws. CO4 APPLY ANALYZE Apply the knowledge of electromagnetics to understand and analyze the motion of charge particle in electric and magnetic field which leads to the different kind of drifts in plasma. Also apply the knowledge of these drifts to understand the naturally formed Van Allen radiation belt by trapping the charged particles approaching earth from solar or galactic origin.
B.Sc. in Physics (PHMDC-114P)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 REMEMBER UNDERSTAND Set up the instruments as per the instructions, Connect the circuit as given in the circuit diagram. CO2 UNDERSTAND APPLY Develop measurements techniques, record observations, use the given formula, do calculations and draw your conclusion from the result. CO3 EVALUATE Find uncertainty involved in the observations CO4 ANALYSE Analyse the observations for scientific inference
B.Sc. in Physics (PHM-113T)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 REMEMBER UNDERSTAND Understand scalars, vectors, product of vectors and their applications, Learning the concept of Gradient, the Divergence theorem. Gauss’s law, The curl and Stoke’s theorem. CO2 REMEMBER UNDERSTAND Remember basic concepts of semiconductor diode, design rectifier circuits, study important aspects of rectifier circuits, and know about the Characteristics of transistor, load line analysis, operating point, cut off and saturation points.
B.Sc. in Physics (PHM-112P)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 REMEMBER UNDERSTAND Set up the instruments as per the instructions, Connect the circuit as given in the circuit diagram. CO2 UNDERSTAND APPLY Develop measurements techniques, record observations, use the given formula, do calculations and draw your conclusion from the result. CO3 EVALUATE Find uncertainty involved in the observations CO4 ANALYSE Analyse the observations for scientific inference
B.Sc. in Physics (PHM-111T)
Course Outcomes CO COGNITIVE ABILITIES COURSE OUTCOMES CO1 REMEMBER UNDERSTAND Understand scalars, vectors, product of vectors and their applications, Learning the concept of Gradient, the Divergence theorem. Gauss’s law, The curl and Stoke’s theorem. CO2 REMEMBER UNDERSTAND Remember basic concepts of semiconductor diode, design rectifier circuits, study important aspects of rectifier circuits, and know about the Characteristics of transistor, load line analysis, operating point, cut off and saturation points. CO3 REMEMBER UNDERSTAND ANALYSE Understand basic concepts of optics in the interference and its applications; Fermat’s Principle and its application; Use of matrix method to analyse complex optical systems CO4 REMEMBER UNDERSTAND Recall Waves and oscillations and describe basic concepts related to Composition of two S.H.M. Lissajous figures, forced vibration, amplitude resonance, Understand the difference between velocity of longitudinal wave in a solid medium and velocity of transverse wave along a stretched string
