users.physics.ox.ac.uk/~lvovsky/B3/ contain assorted PDFs from between 2015 and 2019
Syllabus reads:
  • Multi-electron atoms: central field approximation, electron configurations, shell structure, residual electrostatic interaction, spin orbit coupling (fine structure).
  • Spectra and energy levels: Term symbols, selection rules, X-ray notation, Auger transitions.
  • Hyperfine structure; effects of magnetic fields on fine and hyperfine structure. Presumably Zeeman effect.
  • Two level system in a classical light field: Rabi oscillations and Ramsey fringes, decaying states; Einstein
  • A and B coefficients; homogeneous and inhomogeneous broadening of spectral lines; rate equations.
  • Optical absorption and gain: population inversion in 3- and 4-level systems; optical gain cross section; saturated absorption and gain.
Professor in 2000s seems to be
But as of 2023 marked emeritus, so who took over?
Ewart is actually religious:
This dude is pure trouble for Oxford!
www-thphys.physics.ox.ac.uk/people/AndreiStarinets/sr_mt_2022.html (archive) contains 2022 problem sets and notes, well done Mr Andrei Starinets!
www-pnp.physics.ox.ac.uk/~barra/teaching.shtml As of 2023, contains some good 2015 materials: web.archive.org/web/20220525094139/http://www-pnp.physics.ox.ac.uk/~barra/teaching.shtml It was called "Subatomic physics" back then.
2015 professor: Alan J. Barr.
Possible 2022 professor: Guy Wilkinson (unconfirmed): www.chch.ox.ac.uk/staff/professor-guy-wilkinson
users.ox.ac.uk/~corp0014/B6-lectures.html gives a syllabus:
  • Heat capacity in solids, localised harmonic oscillator models (Dulong-Petit law and Einstein model)
  • Heat capacity in solids, a model of sound waves (Debye model)
  • A gas of classical charged particles (Drude theory)
  • A gas of charged fermions (Sommerfeld theory)
  • Bonding
  • Microscopic theory of vibrations: the 1D monatomic harmonic chain. Mike Glazer's Chainplot program.
  • Microscopic theory of vibrations: the 1D diatomic harmonic chain
  • Microscopic theory of electrons in solids: the 1D tight-binding chain
  • Geometry of solids: crystal structure in real space. VESTA, 3D visualization program for structural models; an example crystal structure database.
  • Geometry of solids: real space and reciprocal space. Reciprocal Space teaching and learning package.
  • Reciprocal space and scattering. A fun way to discover the world of crystals and their symmetries through diffraction.
  • Scattering experiments II
  • Scattering experiments III
  • Waves in reciprocal space
  • Nearly-free electron model
  • Band structure and optical properties
  • Dynamics of electrons in bands
  • Semiconductor devices. Intel's "A History of Innovation"; Moore's Law; From Sand to Circuits.
  • Magnetic properties of atoms
  • Collective magnetism. A micromagnetic simulation tool, The Object Oriented MicroMagnetic Framework (OOMMF); OOMMF movies of magnetic domains and domain reversal.
  • Mean field theory
Problem set dated 2015: users.ox.ac.uk/~corp0014/B6-materials/B6_Problems.pdf Marked by: A. Ardavan and T. Hesjedal. Some more stuff under: users.ox.ac.uk/~corp0014/B6-materials/
The book is the fully commercial The Oxford Solid State Basics.
Students choose only one of the Cx courses.
Then there are PhDs corresponding to each of them: www.ox.ac.uk/admissions/graduate/courses/mpls/physics
Video 1.
A very honest review of my Oxford University master's degree (theoretical physics at keble college) by alicedoesphysics (2020)
Source. Basically all her courses are from the Mathematical Institute of the University of Oxford, and therefore show up at the Moodle of the Oxford Mathematics Institute of Oxford.
Interesting presentation cycle at Merton BTW: www.arturekert.org/teaching/merton
Artur looks like a cool teacher.

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