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Difference between revisions of "Teaching"

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* Quantum mechanics (4AP003, Lectures & Tutorials; Module leader):
* Quantum mechanics (4AP003, Lectures & Tutorials; Module leader):
**Lectures:
**Lectures:
*** Lectures 1 & 2: Random Variables
*** Lectures 1 & 2: Random Variables [https://wlv.cloud.panopto.eu/Panopto/Pages/Viewer.aspx?id=5bae2d95-970c-4f0f-a8cb-aca8016c34e2 <i class="fa fa-video-camera" aria-hidden="true"></I>] [[:Media:4AP003_-_Lectures_1_and_2-Random_Variables.pdf|<i class="fa fa-file-pdf-o" aria-hidden="true"></i>]]


* Solid State Physics (5AP002, Lectures & Tutorials; Module leader):  
* Solid State Physics (5AP002, Lectures & Tutorials; Module leader):  

Revision as of 00:36, 7 January 2021


Courses taught at the University of Wolverhampton

2020/21

  • Quantum mechanics (4AP003, Lectures & Tutorials; Module leader):
    • Lectures:
      • Lectures 1 & 2: Random Variables
  • Solid State Physics (5AP002, Lectures & Tutorials; Module leader):
    • Lectures:
      • Lecture 1: Introduction to lattices
      • Lecture 2: Bravais lattices
      • Lecture 3: Reciprocal lattices
      • Lecture 4: Bragg law and diffraction condition
      • Lecture 5: Van der Waals and Lennard-Jones potentials
      • Lecture 6: Coupled harmonic oscillators
      • Lecture 7: Introduction to phonons
      • Lecture 8: More about phonons
      • Lecture 9: Density of states
      • Lecture 10: Obtaining the density of states
      • Lecture 11: Debye model
      • Lecture 12: Einstein model and electron gas
      • Lecture 13: Free electron gas in 3D
      • Lecture 14: Contribution of electrons to the heat capacity and electric conductivity
      • Lecture 15: The Hall effect and the origin of the energy gap
      • Lecture 16: Energy gap and Kronig-Penney model
      • Lecture 17: The central equation
      • Lecture 18: Energy gap at the boundary of the Brillouin zone
      • Lecture 19: Semiconductors
      • Lecture 20: Electrons and holes in semiconductors
      • Lecture 21: Intrinsic carrier concentration
      • Lecture 22: Doped semiconductors
    • Experiments:
  • Research I (6AP003, Lectures & Tutorials):
    • Seminars:
      • Seminar 13: The two-level system
      • Seminar 14: Application of Heisenberg equation
      • Seminar 15: The density matrix
      • Seminar 16: Dissipation
      • Seminar 17: Decay and incoherent driving
      • Seminar 18: Quantum trajectories
      • Seminar 19: Quantum jumps
      • Seminar 20: Spontaneous emission
      • Seminar 21: Quantum Monte Carlo

2019/20

  • Quantum Mechanics (4AP003, Lectures; Module leader): This module was taking place when COVID-19 broke out in Europe and we had to turned it into an online course. The recordings of the lectures are on the links below.
    • Lecture 10: Solutions to the harmonic oscillator
    • Lecture 11: Free particle
    • Lecture 12: Reciprocal space
    • Lecture 13: Uncertainty principle
    • Lecture 14: Bound state of the $\delta$-potential
    • Lecture 15: Scattering states of the $\delta$-potential
    • Lecture 16: Bound states of the finite square well potential
    • Lecture 17: The Hilbert space
    • Lecture 18: Operators in the Hilbert space
    • Lecture 19: Postulates of Quantum Mechanics
    • Lecture 20: Bosons: ladder operators and coherent states
    • Lecture 21: Fermions: the two-level system and Pauli matrices
    • Lecture 22: Rabi oscillations
  • Electromagnetism I (4AP004, Tutorials)
  • Solid State Physics (5AP002, Lectures & Tutorials; Module leader)
  • Electromagnetism II (5AP001, Tutorials)

2018/19

  • Quantum Mechanics (4AP003, Tutorials)
  • Electromagnetism I (4AP004, Lectures & Tutorials; Module leader)
  • Optics (4AP001, Tutorials)
  • Solid State Physics (5AP002, Lectures & Tutorials; Module leader)
  • Electromagnetism II (5AP001, Tutorials)
  • Thermodynamics & Statistical Physics (5AP004, Tutorials)
  • Quantum Physics (5AP005, Tutorials)
  • Mathematical Methods (5AP004, Tutorials)