ABOUT THE COURSE:The course aims to introduce and work through the underlying concepts behind magnetism and superconductivity. Starting from an electron in a magnetic field, the magnetic response of a collection of atoms in a solid are all worked out. Magnetization and susceptibility in para and diamagnetic cases, their applications and excitations are discussed. Superconductivity: zero resistance, Meissner effect, perfect diamagnetism; BCS theory, energy gap, isotope effect and tunneling experiments worked out. Josephson junctions and their applications, qubits and quantum chips discussed. Novel high-TC superconductor introduced. The emphasis is on working things out from very simple physical concepts.INTENDED AUDIENCE:B Tech, BE, M Tech, ME, MSc, PhDPREREQUISITES:Modern physics and elementary quantum mechanics, basic ideas in condensed matter or solid-state physicsINDUSTRY SUPPORT:Microsoft, IBM, AT&T, Accenture, google quantum AI, Philips, DRDO, Intel, BEL, Infineon technologies, Samsung, LG, Silfab and such others
Concepts in Magnetism and Superconductivity
Indian Institute of Technology, Kharagpur and NPTEL via Swayam
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122
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Overview
Syllabus
Week 1: The magnetic moment, Bohr magneton, canonical momentum, Bohr-van Leeuwen theorem. Magnetisation and susceptibility; an isolated atom in a magnetic field, dia, para and ferromagnetic susceptibilities. Ground state of ions – Hund’s rules. Van Vleck paramagnetism.
Week 2:Magnetization of a collection of independent ions: Curie’s Law. Adiabatic demagnetization, Pauli paramagnetism. Ions in a solid: Crystal field, Orbital quenching, Jahn-Teller effect.
Week 3:Magnetic resonance technique: NMR and ESR, Mossbauer. Long range order, magnetic interactions, relevant energy scales, dipolar interaction and origin of exchange: 2-electron system, singlet-triplet splitting-Spin Hamiltonian.
Week 4:Direct exchange, super-exchange, indirect exchange and itinerant exchange. Magnetic impurity, spin-glass and RKKY interaction, magnetic multi-layers and the concept of GMR. Spin models, mean-field theory and exact solution of 1D Ising model.
Week 5:Absence of LRO and Mermin-Wagner theorem, Ferromagnetic Heisenberg model, ground state and excitations; Antiferromagnetism and the concept of frustrated spin systems.
Week 6:Absence of LRO and Mermin-Wagner theorem, Ferromagnetic Heisenberg model, ground state and excitations; Antiferromagnetism and the concept of frustrated spin systems.
Week 7:BCS theory, energy gap, isotope effect, transition temperature, Specific Heat. Type-I, Type-II superconductors, Abrikosov vortices.
Week 8:Quantum interference, Josephson effect, superconducting junctions, squid and its applications, qubits and quantum chips. Novel superconductors.
Taught by
Prof. Arghya Taraphder
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Reviews
5.0 rating, based on 1 Class Central review
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Nice Course. Starting from the very basics of the magnetism and then going through the superconductors, this course will guide you to the modern concept of quantum computer. Useful and timely course.