BTEEOEL 305B: Applied Physics Syllabus for EE 3rd Sem 2018-19 DBATU (Elective-I)

Applied Physics detailed syllabus scheme for Electrical Engineering (EE), 2018-19 onwards has been taken from the DBATU official website and presented for the Bachelor of Technology students. For Subject Code, Course Title, Lecutres, Tutorials, Practice, Credits, and other information, do visit full semester subjects post given below.

For 3rd Sem Scheme of Electrical Engineering (EE), 2018-19 Onwards, do visit EE 3rd Sem Scheme, 2018-19 Onwards. For the Elective-I scheme of 3rd Sem 2018-19 onwards, refer to EE 3rd Sem Elective-I Scheme 2018-19 Onwards. The detail syllabus for applied physics is as follows.

Applied Physics Syllabus for Electrical Engineering (EE) 2nd Year 3rd Sem 2018-19 DBATU

Pre-requisite:

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Course Outcomes:

1. Understand concept of Electromagnetic theory and Magnetism
2. Understand concept od Dielectric and Super conductivity
3. Understand concept of nanomaterial

Unit 1

Electromagnetic Theory covering, Coulomb”s law for distribution of charges, Polarization Gauss”s law, Electric current and equation of continuity, Magnetic induction and Lorentz force, Steady current and Biot-Savert law, Ampere”s law, Magnetization and magnetic intensity, Faradays law of induction, Generalization of Ampere”s law, Maxwell”s equations

Unit 2

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Unit 3

Magnetism : Magnetic field and Magnetization; Magnetic susceptibility, Paramagnetism – Paramagnetism due to partially filled shells, transition elements (3d), rare earths (4f) and actinides, Magnetization and total angular momentum (definition and relationship); Concept of magnetic moment, gyromagnetic ratio, Lande”s g-factor, Bohr Magneton, Curie”s Law – derivation for spin only” system (L = 0), expression for non-zero orbital angular momentum system (J = L + S); Ferromagnetism, antiferromagnetism, and ferrimagnetism; Exchange interaction between magnetic ions; Molecular field, Expression for Curie-Weiss law, concept of 0P ;Ferromagnetism and Ferrimagnetism – Curie temperature, hysteresis, Hard ferromagnets, permanent magnets – Sm

Nd2Fe14B, Sintered Alnico, Sintered Ferrite – 3 etc. – Comparison and applications; Soft ferromagnets -Permalloys, Ferrites etc. – Comparison and applications; Neel temperature, Curie-Weiss law; Magnetic resonance, NMR and MRI, MASER;

Unit 4

Superconductivity :Zero resistance, Critical temperature Tc ,Perfect diamagnetism, Meissner effect, Critical field Hc, Type I and Type II superconductors, Cooper pairs and formation of superconducting gap at Fermi level, Electron-Phonon interaction and BCS theory, Isotope effect, Applications – Superconducting magnets, Transmission lines, Josephson effect (DC and AC, qualitative), SQUID; (7 Lectures)

Unit 5

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Unit 6

Quantum Computation and Communication covering, the idea of qubit” and examples of single qubit logic gates- Classical bits, Qubit as a two level system; Bloch vector representation of state of qubit; Polarization states of photon and measurements; Pauli gates, Hadamard gate, Phase shift gate, Quantum gates as rotations in Bloch sphere; EPR paradox, concept of entanglement and Bell”s inequality- The paradox, joint state of entangled particles; Proof of Bell”s inequality; Two-qubit controlled gates; entanglement generation and the Bell basis- Generic twoqubit state, Controlled-NOT gate; Quantum circuit for transforming computational basis to Bell basis; Qualitative discussion on the circuit” model of quantum computation; An overview of classical cryptography: Vernam cypher; Public key cryptosystem; The Rivest-Shamir-Adleman” or RSA” protocol; Comments on No-cloning theorem and impossibility of faster-than-light transfer of information; The BB84 protocol in quantum cryptography- The protocol; its validity on the basis of Heisenberg”s uncertainty principle; Quantum Teleportation- Basic idea; measurement using Bell operator, need for classical communication channel; quantum circuit describing teleportation protocol;

Reference Book:

1. Kittel C., Introduction to Solid State Physics, Wiley Eastern
2. Callister W.C. Jr., Material Science and Engineering: An Introduction, 6th Edn., John Wiley and Sons
3. Kulkarni Sulabha K., Nanotechnology: Principles and Practices, Capitol Publishing Co.
4. Charles P. Poole, Jr., Frank J. Owens, Introduction to Nanotechnology, Wiley Eastern
5. Nielsen M. A., I. L. Chuang, Quantum Computation and Quantum Information, Cambridge Univ. Press

For detail syllabus of all subjects of Electrical Engineering (EE) 3rd Sem 2018-19 onwards, visit EE 3rd Sem Subjects of 2018-19 Onwards.