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• students typically have had little experience making the connection between microscopic and macroscopic phenomena,
• a deep understanding of the probability theory is important,
• the solution of a single equation or a set of equations such as Newton laws, Maxwell equations, or Schrodinger equation is not central to statistical physics, so that there are no standard procedures that work for a large class of problems and many calculations are unfamiliar to students,
• there are few exactly solvable problems.

Thus, the course will focus

with application to 

areas of relevance to research in DPA, such as magnetism, condensed

• proper and improper mixed states in quantum mechanics and the density operator,
• entanglement and decoherence in quantum mechanics,
• equilibrium partition function for noninteracting bosons and fermions,
• electrons in solids,
• stellar astrophysics,
• Bose-Einstein condensation in cold atomic gases,
• phase transitions and critical phenomena (with emphasis on magnetic systems),
• mean field theory vs. renormalization group methods,
• quantum phase transitions,
• elements of nonequilibrium statistical physics: Boltzmann equation, Kubo formula and quantum master equations.

• Homework Set 2 is posted and due on 03/20.

• Lecture 2: Density operator formalism for proper and improper mixed quantum states.

• Stelar evolution: The life and death of stars
• Quantum statistical mechanics for stellar astrophysics: White dwarfs, neutron and quark stars and black holes
• Bose-Einstein condensation in ultracold atomic gases
• Tutorial on renormalization group applied to classical and quantum critical phenomena
• Elements of nonequilibrium statistical physics: Boltzmann equation and Kubo formula