Explores spin relaxation mechanisms, perturbation theory, relaxation rates, momentum conservation, phonon drag, electron-magnon interactions, and symmetries.
Covers the fundamentals of spectroscopy, including tools, color, Doppler effect, and molecular behavior.
Covers quantum sensing with single spins, focusing on the Nitrogen-Vacancy center in diamond and its applications in antiferromagnetic materials.
Explores the Nuclear Overhauser effect in magnetic resonance and its impact on spin relaxation and enhancement.
Explores the quantum principles behind Pulsed NMR Spectroscopy, including Zeeman interaction and spin manipulation through radiofrequency irradiation.
Explores spin qubits in quantum dots, real-time single-electron detection, tunneling response, energy-selective readout, T₁ relaxation time, spin relaxation, and coherent spin control.
Explores spin as angular momentum, its operators, commutation relations, and eigenstates in quantum mechanics.
Introduces Dynamic Nuclear Polarization in magnetic resonance, emphasizing efficient nuclear spin diffusion and the impact of electron concentration.
Explores spin-spin couplings in NMR, covering equivalent nuclei, molecular symmetry, ³1P NMR spectra, and strong coupling effects.
Explores the fundamentals of exchange interactions, including intra-atomic and inter-atomic exchange, spin-orbit coupling, and Dzyaloshinskii-Moryia coupling.
