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Department of Physics, RTMNU

Name of Programme: M.Sc Physics

Programme specific outcome

After completion of course, the student will be to:

PSOl: Understanding basic principles of Physics which are underlying a wide selection of physical phenomenon.

PSO2: Explore with current state-of-art in the selected area of Physics.

PsO3: lnculcate the habit to plan, design and execute new experiment. Analyze, interpret experimental result and write report on it.

PSO4: Assess the errors involved in an experiment work; searching out and adopting new methodology to reduce errors. Presents the experimental

outcome in effective ma nner.

Psos: After completing PG degree from this programme, they will be eligible to continue research at the higher degree (Ph.D) level. They will be trained by

experimental, computer programming and data interpretation programming skill and exposed to improve their employability in research and development,

in scientific and engineering industries.

PSo6: Additionally, they will have necessary numerical and transferable skills to select general career choice such as accounting or computing.

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Programme matrixName of Programme: M.Sc PhYsics

(Low Correlation = L/1; Moderate Correlation = M12 and High Correlation = H/3)

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co Program Outcomes Program Specific Outcomes (PSOs)

Course Name: 1T1 Mathematical Physics Domain Specific

POSl POS2 POS3 POS4 POS5 POSS

co1 Curvilinear co-ordinate Systems, Physical

ideas about gradient, Applications to the

solution of differential equations.

H M H M H M

co2 Elementary ideas about tensors, Cartesian

tensors, differential of Cartesian tensors,gradient, divergence and curl , Laplacian ofCartesian tensors, Laplace transform ofelem functions.

H M H M H M

co3 Linear vector spaces - linear independentbases, Dimensionality, inner product,

matrices, linear transformation,Orthogonal and Unitary matrices, Cayley

Hamilton theorem.

H H H H M

c04 Linear differential equations, Special

Function- Laguerre, Hermite, Legendrepolynomials, Special Bessel's function.

H M H H M M

Course Name: 1T2:Complex Analysis and

Numerical Methods

Domain Specific

co1 Solve simple problems involving complex

algebra such as rationalization.H M L L M L

co2 Given a function, determine if it is analytic'lntegrate various functions using calculus

of residues.

1 H H L L H

co3 Compute pole expansion and product M L H M L M

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expansion of certain functions.

co4 Find the roots of a given nonlinearfunction.

L L L H M M

co5 For a given data, fit a function, interpolateor extrapolate as necessary.

L L M M H M

co5 Solve ordinary differential equations.

Compute integrals numericallY .

M M M L L H

Course Name: 1T3:Electronic

co1 Clear the conceptual knowledge of

Semiconductor discrete devices, Bipolarjunction transistor (JFET, MOSFET, SCR,

UJT), Opto-electronic devices like Photo-

diode, solar cell, LED, LCD and Phototra nsistor.

H L L L H L

co2 Gains the knowledge of applications ofsemiconductor devices in linear and digitalcircuits, transistor as amplifier, coupling ofamplifier, feedback in amplifiers and types

of oscillators clipping and clamping

circults also gets the knowledge of

transistor as a switch OR, AND and NOT

and Gates.

M H L L M L

co3 Explores the fleld of Digital integratedclrcuits- NAND and NOR gates buildingblock, simple combinational Circults,

Multivibrators, sweep generator, shiftregisters, counters, coverters,

semiconductor memories (ROM, RAM, and

EPROM) along with architecture of 8 bitm r NTEL 808s)

H M M

co4 Gain understandlng of Linear integratedcircuits- Operational amplifier and itsa cations-lnverti and noninverti

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Domain Specific

amplifier, adder, integrator, differentiator,waveform generator, comparator andSchmittrigger, Butterwoth active filter,phase shifter.

co5 Understand the CommunicationElectronics in terms of Basic principle ofamplitude frequency and phasemodulation also Simple circuits foramplitude modulation and demodulation,digital (PCM) modulation anddemodulation.

H H H

Course Name: 1T4:Electrodynamics-l Domain Specific

co1 Familiar with the static properties ofelectric and netic fields

H M H H H L

co2 Understand the concept of electric fieldand they should be able to solve problems

M L H H H L

co3 Familiar with the definition of electriccurrent and electric current density. Theyshould understand the importantinformation contained in the equation ofcontinuity and they should be able to solvesimple problems involving this equation.

M H M H H L

co4 Understanding the concept of themagnetic field and be able to calculate thisfrom given current distributions.

H H H H M H

cos Understand how the Maxwell equationsarise as a synthesis of the variousindividual electromagnetic phenomenaand know how Maxwell's equations leadto electromagnetic waves.

H H H H M H

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Course Name: t=ZTL:. QuantumMechanics I

Domain Specific

co1 construct operators in coordinate and

momentum representation.H H M M L L

co2 familiar with Dirac notation, notions ofinner and outer product and basic

mathematical structure.

H H L M M L

co3 wrlte matrix representation for a given

operator, understand various

transformations and diagonalization.

M L H L L M

co4 Understand tunnelling, parity ofeigenfunctions,

L L H M M

co5 frame a radial equatlon for a given central

force problem and solve it.L L M H H L

co6 findClebsch-Gordon coefficients foradditlon of angular momenta.

L L M M L H

Course Name: Statistical Physics Domain Specific

co1 Understand basics of theory of probability

and statistical approach forthermodynamical properties.

H H H H M M

co2 Galn the knowledge of theory ofIndistinguishable particles for fifth state ofmatter l.e Bose Einstein condensate.

H H H L M L

co3 Demonstrate Fermi Dirac condensatlon on

the basis of BCS theory and its applicationfor free electron gas in metal.

H H H L M L

co4 Describe phase transition phenomenon

using lsing model and Landau theory.H H H L L L

Course Name: 2T3:Classical Mechanics Domain Specific

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co1 Solve simple systems by writingLagra ngia n.

H L H L L L

co2 Understand cyclic coordinates, canonicaltransf ormations.

M H H L L L

co3 Compute Poisson brackets, interpret them L L L H H Mco4 Understand central force motion and

Interpret scattering cross-section.L L L M H M

co5 Understand Euler angles, lnertia tensor.Compute equations of motion for simplecoupled systems.

L L L H H L

co5 Learn Hamilton-Jacobi theory and itsimportance.

L L L M M H

Course Name: 2T4:Electrodynamics-ll Domain Specific

co1 Use of Maxwell equations in analysingtheelectromagnetic field due to time varyingcharge and current distribution

H H M M H L

co2 describethe nature of electromagneticwave and its propagation throughdifferent media and interfaces.

H H H M M H

co3 explaincharged particle dynamics and

radiation from localized time varyingelectromagnetic sources

H H M H M

co4 Formulate and solve electrodynamicproblems in relativistically covariant formin four-dimensional space-time

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cos be familiar with some elementaryphenomena and concepts in quantumelectrodynamics.

H H H M H M

Course Name: 1=2T1 Quantum MechanicsI

Domain Specific

co1 Solve simple problems using perturbationtheory.

H H M M L L

co2 Solve simple problems of perturbationtheory, understand symmetries ofwavefunction.

M H H M L L

co3 Solve simple problems involving timedependent perturbation.

L H H M M L

co4 Solve barrier problem using WKB method L H H H L L

cos Understand the physical meaning ofscattering coefficients. Difference betweenbosons and fermions.

L L L M H M

co5 know about Klein-Gordon equations, Dirac

equations. Solve for Hydrogen atom using

Dirac's theory.

L L L L M H

Course Name: 3T2 Solid state Physics andSpectroscopy

Domain Specific

co1 Clear basic concept of crystal classes,

lattices, symmetries and to understand therelationship between real and reciprocallattice.

H H M M L M

co2 Understanding the correlation ofcrystallography with experimental crystalstudy by Braggs conditions for X-ray

diffraction.

H M H H L L

co3 Explore with the knowledge of differentcrystal defect and its influence on basicphysical behaviour of crystals.

H H H M M(t-

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co4 Gain basic knowledge of dielectricproperties of materials and learn the basicof the dielectric behaviour of variousmaterials.

H M M M H L

co5 Describe the spectra of single and multipleelectrons atoms including fine andhyperfine structure of alkaline, Helium likeatoms, spin and relativity correction,different type of coupling such as L-S andJ-J couplings.

H M M M L L

co5 Analyse the spectra of dlatomic moleculessuch as electronic, rotational, vibrationalspectra and a basic introductory ideaabout the Raman Spectroscopy.

H H H M M H

co7 Explain effect of electric and magnetic fieldon the atomic spectrum.

M H

H

H L L

Course Name: E1.2:X-rays-l Domain Specificco1 Easlc concepts of production of X-rays,

Designing concepts conventional of X-raygenerators, Basics of Advanced radiationsource Synchrotron and its advantagesover conventional sources.

H H M L H L

co2 Understanding of interaction of X-rayswith the matter, Applications of X-raysbased on different physical processesinvolved after interaction of x-rays withmatter.

H H H M H L

co3 Understandlng the method of X-ray H H H M H L

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radiography and its applications in medicaland industrial fields. Details of materialscharacterization techniques based on X-

ray photoelectron/Auger electronspectroscopies and X- ray fluorescencespectroscopy.

co4 Designing concepts of different x-rayspectrographs, Understanding theconcepts and methods of x-ray detection.Gainlng the knowledge to select properspectrograph and detectors for particularapplicatlon.

H H H H H L

co5 Different theoretlcal concepts regarding x-

ray spectra and their interpretation.Knowledge about calculating relativeintensities of spectral lines.

H M M L M M

lnterpretation of X-ray absorption spectra.Experimental techniques for obtaining X-

ray absorption spectra and its importantapplications.

H H H H H M

co7 Understanding the concept of dispersionof X-rays and its slgnificance.

H L L L H L

Course Name: E1.3:Nanoscience andNanotechnology

Domain Specific

co1 Clear basic concept of quantum approachfor density of states for quantum well,wires and dots.

H M H H H

co2 Understanding the different methods ofsynthesis of nanomaterials.

H H H H H

co3 Explore with the knowledge of differentinstrumentation useful to analyse

H H H H H

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Page 9 of 14

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materials at nanoscale.

co4 Understanding the propertiesnanomaterials for technology application

H M H H H

Course Name: 4T1: Nuclear and ParticlePhysics

Domain Specific

co1 Clear basic concept of nuclear properties;its size, radii, shape charge distribution,spin, parity, mass, nuclear stability and

also to understand binding energy, semiempirical mass formula, liquid drop model,laws of radioactive decay.

H M M L M L

co2 Understands elements of deuteronproblem, n-n scattering, chargeindependence, and symmetry of nuclearforces along with electric and magneticmoments of nuclei.

H M H M L L

co3 Gains the knowledge of elementaryparticles, decay of nuclei, theirclassiflcation, characteristics, selection ruleand their theories.

H H H L M L

c04 Explores the field of nuclear reactions,conservation laws, mecha nism, cross

section, compound nucleus along withfission and fusion reactions, nuclearenergy and elements of nuclear power.

H M L L L L

co5 Explains the interaction of char5gedparticles and electromagnetic radiationwith matter along with principles ofradiation detectors including G-M Counter,proportional counter, Na(Tl) Scintillationdetectors, semiconductor detectors.

H H M M L L

Describepa rti cl es,

classificationstrong,

of elementaryweak and

M M L L M H

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electrom eticagn intera ctions also will beable to UN de rsta n d Gel alam nn isN hijimaform ula withalong pro perties ofelementa rY clparti anes d th rei sym metrynd conse rvation WSlaco1

ergy,

Clear bas ic ofconcept n ucle r properties;its size, rad ashii, chape distributirge o[,paspin, mity nass, U clea r sta b ndilitya lso to u dnderstan bind ening

S emempir cal m ass li uiformula, dq mdrop odeoflaws dira oactive d

H M t L L t

Course Name: 4T2 Solid State PhysicssDomain lpecificco1 dBan theo BIrY, och th theeorem, Kron ig-Pen odmney constru€1, ction of Bril lou inzones, exte nded nd reduced ezonschemes,

UMQuant theory ofrap magnetis m, exch nge inte ractions.Pa U lisetic ibil

M H H M H H

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Petit's

ttiLa ce dynam enCS, ergy of catomimot aions, di a batic pri harnciple, m coniprproxi mation Theor ofes lattice specifich Deat, ndaulong law insE tein a ndmodels

H M M H H H

co3eory,reF ele ectron th el ectrons movi inngone an d th ree d im ension a potentia wel ls,uantumq

astate dnd ne 'aege denscY, ofityelstates, ectrical nd the 'm al conductivityof metalrs, semi conductors, free carrierconcentrati on n semico ndu Fctors, ermlevel n d rca rrie con centration nse mi

H M H M H H

co4ll super

uctivity,dSuperconcondu cto fS, Meissn er

Type I and M H H H M H

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London equ

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ation, coherence

junction, high

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effect,length

cDomain2;4T3E2NameCourse

LHLLLHattices,cl €S,assof crYstaConcePts chill pograofs Crystamethod€S,metrisym upsgront spaceoi PS,P grouon5,P roiectish pationrelthendrstadeuntodan

latticerocared cianrealnbetwee

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LMLLMHXntfferediofgrstandinundeConcePtuan X-raYnvolvedSrocesseringScatte pray

diffraction

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MHHMMHlograPhYCrystalx-rayofBasisPhysical nteto rpretcocal ncePtsretieothntreDiffeondiffractieannda

co3

MHHHHHnt X-raY

techniquesfferediofonatitrS'Demonntalmeb exPerisednractiodifft

norizaticharactealsriatemforused

co4

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x-r diffraction techni ue

ephasdiff ,erentoftionlnter pretausils ngateriamnonon phenomenformati

co5

LHMMHHondiffractintrediffeofsonCom parion.diffractix-ofthatwithnitech ques

,.,1anntagesdisadvantages,Advaicabi

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Domain Specificame: E2.3:4'

Nanotech

T3:NanosciencernologY ll

andCourse N

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Page 12 of 14

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co2 Familiar with concept of Nanophotonicsand tuning the optical propertiesnanomaterials and their use in differentapplications.

H H H H M L

co3 Understand the concept of Nanomagneticsand magnetic propertles of nanomaterials.

H L M H H L

co4 Understanding the electronic properties ofnanomaterials and how to use theseproperties in making the electronic devices

of current trends.

H M H H H M

co5 be familiar with different nanocompositematerials and their synthesis techniquesand the need of nanocomposite forcurrent and future applications.

H L H M H M

Course Name: 52.2-4T4:ExperimentalTechniques in Physics

Domain Specific

co1 Explain different types of radiation, theirsources and detectors which are

commonly used in experimentaltechniques.

H H M H H H

co2 Clear the conceptual understanding offunctionality of different types of sensors

H M L M L

co3 Demonstrate different X-ray and thermalanalysis based experlmental techniquesused for materials characterization in

Physics

H H M L M M

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Page 13 of 14

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co4 Describe different electron microscopictechniques for morphological studies ofmaterials.

M M H L H M

co5 Gain understanding of magnetic behaviourof materials and different tools formagnetic characterization of materials.

H L L L M H

co5 Explore with different spectroscopicanalysis techniques

M M H H H M

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