{"id":56,"date":"2019-11-07T11:27:02","date_gmt":"2019-11-07T16:27:02","guid":{"rendered":"https:\/\/www.bu.edu\/physics\/graduate\/"},"modified":"2025-01-07T16:55:35","modified_gmt":"2025-01-07T21:55:35","slug":"graduate","status":"publish","type":"page","link":"https:\/\/www.bu.edu\/physics\/graduate-program\/graduate\/","title":{"rendered":"Graduate Courses"},"content":{"rendered":"<div class=\"course-feed\"><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">501<\/span><\/span> Mathematical Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASMA226 & CASPY355) or equivalent. - Graduate Prerequisites: (CASMA226 & CASPY355) or equivalent. - Introduction to complex variables and residue calculus, asymptotic methods, and conformal mapping; integral transforms; ordinary and partial differential equations; non-linear equations; integral equations. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">502<\/span><\/span> Computational Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: consent of instructor. - Graduate Prerequisites: consent of instructor. - Fundamental methods of computational physics and applications; numerical algorithms; linear algebra, differential equations; computer simulation; vectorization, parallelism, and optimization. Examples and projects on scientific applications. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">511<\/span><\/span> Quantum Mechanics I<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY451 & CASPY452) - Graduate Prerequisites: (CASPY451 & CASPY452) - General theory of quantum mechanics, including the Schrodinger, Heisenberg, and interaction pictures. The path integral formulation. Angular momentum: orbital and spin angular momentum, addition of angular momenta, Wigner-Eckart theorem. Scattering theory: time-independent, partial waves and phase shift, identical particles, time dependent, and propagators. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">512<\/span><\/span> Quantum Mechanics II<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY511) - Graduate Prerequisites: (CASPY511) - Continuation of CAS PY 511. Degenerate and nondegenerate perturbation theory. Second quantization of nonrelativistic systems with applications to scattering, lifetime of excited atomic states, many-body problems. Relativistic quantum mechanics: Klein-Gordon equation, Dirac equation. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">521<\/span><\/span> Electromagnetic Theory I<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY405) - Graduate Prerequisites: (CASPY405) - Vector and tensor analysis. Electrostatics, uniqueness, electrostatic energy, capacitance. Boundary value problems, conformal mapping, variable separation, Green's functions. Multipole expansion, electric polarization, atomic models, anisotropic media. Contour integration and application to frequency-dependent dielectric constant. Dielectrics, electrostatic energy, boundary value problems. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">536<\/span><\/span> Quantum Computing<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASCS330 OR CASPY354) or equivalent. - Quantum physics as a powerful computational paradigm. Quantum bits (qubits), qubit operations and quantum gates, computation, and algorithms. Computational complexity classes, and efficiency of classical vs. quantum computers. Quantum Fourier transform and Shor's factorization algorithm. Physical implementation of quantum computation. Also offered as CAS CS 536.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">537<\/span><\/span> Quantum Platforms<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Self-contained introduction to physical qubits, control by external fields, pulse sequences, qubit-qubit \ncoupling, qubit-photon coupling, noise and decoherence and mitigation techniques. A survey of \nexperimental quantum device physics: superconducting qubits, neutral atom arrays, solid state and \nspin qubits, ion traps, entangled photons, single molecule circuitry, etc. Brief survey of available \nquantum architectures and software stacks<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">538<\/span><\/span> Interdisciplinary Methods for Quantitative Finance<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY355 OR METAD685) or equivalent; or consent of instructor. - Expands upon the foundations of finance theory with interdisciplinary approaches from statistical physics and machine learning. Equips the students with the Python tools to tackle a broad range of problems in quantitative financial analysis and combines the study of relevant financial concepts with computational implementations. Students learn to use packages like Numpy, Pandas, Statsmodels and Scikit, which are commonly used in research and in the industry.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">541<\/span><\/span> Statistical Mechanics I<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY410) - Graduate Prerequisites: (CASPY410) - Probability theory. Ensembles. Steepest descent methods. Paramagnetism, ideal gas, Einstein model, adsorption isotherms. Thermodynamics, Maxwell relations, heat capacity. Bose and Fermi gases. Electrons in metals, white dwarf stars, black-body radiation, phonons, Bose-Einstein condensation. Interacting systems, virial expansion, Van der Waals gas. Phase transitions: mean-field theories, spin systems. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">542<\/span><\/span> Statistical Mechanics II<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY541) or equivalent. - Graduate Prerequisites: (CASPY541) - Continuation of CAS PY 541; emphasis on applications. Phase transitions: thermodynamic theory of phase transitions, mean field theories (Landau theory). Fluctuations: equilibrium fluctuations, instabilities, fluctuation dissipation theories. Elementary kinetic theory: mean free path approach, Boltzmann equation. Stochastic mathematics: probability theory, Markoff processes, Gaussian processes. Brownian motion: Langevin equations, Fokker-Planck equation. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">543<\/span><\/span> Introduction to Solid State Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY406 & CASPY410 & CASPY451) or consent of instructor. - Graduate Prerequisites: (CASPY406 & CASPY410 & CASPY451) - An introduction to crystal structure; lattice vibrations; electronic energy bands and Fermi surfaces; semiconductors, conductors, and insulators; superconductivity and magnetism. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">551<\/span><\/span> Introduction to Particle Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY451 & CASPY452) - Graduate Prerequisites: (CASPY451 & CASPY452) - Fundamental particles and their symmetries. Isospin and flavor. Discrete symmetries. Phenomenology of weak and strong interactions. Introduction to detector techniques.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">555<\/span><\/span> Cosmological Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY 406 & CASPY 408), or consent of instructor. CASPY 410 is recommended but not required. - Early universe cosmology: inflation, thermodynamics in an expanding universe with radiation, matter, vacuum energy. Growth of density perturbations, cosmic microwave background, large scale structure. The cosmological standard model and open questions, dark matter, dark energy, neutrinos.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">559<\/span><\/span> Quantitative Microbiology<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASBI108 & CASMA121 & CASPY105) or equivalents; or consent of instructor. - QUANT MICROBIO<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">565<\/span><\/span> Dynamics of Nonlinear Systems<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: consent of instructor. - Introduces the modern approach to the dynamics of nonlinear systems, which approach is often called \"nonlinear science,\" a term that stresses the interdisciplinary applications of nonlinear dynamics that go well beyond classical mechanics to include examples from all the natural sciences, engineering, and even social sciences and medicine. Organized around three \"paradigms\" of nonlinear science: (1) chaos and fractals; 2) \"solitons\" and coherent structures; and 3) patterns and pattern selection and will involve analytical, computational, and experimental studies.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">571<\/span><\/span> Introduction to Biological Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY410 OR CASCH352) may be taken concurrently as a co-requisite. - Introduction to biomolecular forces, energy flow, information and thermodynamics in biological systems. Nucleic acid, protein, and biomembrane structure. Mechanisms of transport and signaling in biological membranes. Biophysical techniques including spectroscopy. Emphasis on the physical principles underlying biological structure and function.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">580<\/span><\/span> Machine Learning for Physicists<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY541) or consent of instructor. - Machine learning is one of the most dynamic areas of modern research and application. This class provides an introduction to the core concepts and tools of machine learning in a manner easily understood and intuitive to physicists.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">581<\/span><\/span> Advanced Laboratory<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        <div class=\"cf-hub-ind\">  <a href=\"http:\/\/www.bu.edu\/hub\/what-is-the-hub\/\" target=\"_blank\" class=\"cf-hub-head\" alt=\"BU Hub\">    <span aria-hidden=\"true\" class=\"bu-hub-iconstyles icon-buhub\">BU Hub<\/span>  <\/a>  <a href=\"http:\/\/www.bu.edu\/hub\/what-is-the-hub\/\" target=\"_blank\" class=\"hub-head\">    <span aria-hidden=\"true\" class=\"bu-hub-iconstyles icon-questionmark\">Learn More<\/span>  <\/a>  <ul class=\"cf-hub-offerings\"><li class=\"cf-hub-area-N\">Oral and\/or Signed Communication<\/li><li class=\"cf-hub-area-2\">Research and Information Literacy<\/li><li class=\"cf-hub-area-6\">Writing-Intensive Course<\/li>  <\/ul><\/div>\n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY351) First Year Writing Seminar (e.g., WR 100 or WR 120) - Classical experiments in atomic and nuclear physics, development of new experiments, basic research projects. Experiments include magnetic resonance, nuclear-decay studies, Zeeman effect, holography, black-body radiation, X-ray diffraction, Mossbauer studies, and flux quantization, positron annihilation. Effective Fall 2018, this course fulfills a single unit in each of the following BU Hub areas: Writing-Intensive Course, Oral and\/or Signed Communication, Research and Information Literacy.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">582<\/span><\/span> Quantum Lab<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Experiments in quantum optics and quantum physics, chemistry and engineering to (i) explore basic quantum effects various physical systems, including single photon, entangled photons, Spin systems, superconductivity superconductivity, Integer quantum Hall effect, laser interference, and (ii) experiment with color defects in diamond as qubits implementing the basic single-qubit operations such as initialization, applying quantum gates, and read-out.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">677<\/span><\/span> An Introduction to Evidence-Based Undergraduate STEM Teaching<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">2 credits.<\/span> <span class=\"cf-course-offered\">Fall<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Online course with in-person faculty-led sessions. Participants learn about effective teaching strategies and the research that supports them, and apply approaches to lesson design and assignments for future teaching opportunities. Also offered as GRS BI 677 and GRS CH 677.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">681<\/span><\/span> Electronics for Scientists<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        <div class=\"cf-hub-ind\">  <a href=\"http:\/\/www.bu.edu\/hub\/what-is-the-hub\/\" target=\"_blank\" class=\"cf-hub-head\" alt=\"BU Hub\">    <span aria-hidden=\"true\" class=\"bu-hub-iconstyles icon-buhub\">BU Hub<\/span>  <\/a>  <a href=\"http:\/\/www.bu.edu\/hub\/what-is-the-hub\/\" target=\"_blank\" class=\"hub-head\">    <span aria-hidden=\"true\" class=\"bu-hub-iconstyles icon-questionmark\">Learn More<\/span>  <\/a>  <ul class=\"cf-hub-offerings\"><li class=\"cf-hub-area-4\">Creativity\/Innovation<\/li><li class=\"cf-hub-area-O\">Digital\/Multimedia Expression<\/li><li class=\"cf-hub-area-2\">Research and Information Literacy<\/li>  <\/ul><\/div>\n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASMA124 & (CASPY212 OR CASPY252)) or consent of instructor. - A survey of practical electronics for all College of Arts and Sciences science students wishing to gain a working knowledge of electronic instrumentation, and in particular, its construction. Two four-hour laboratory-lecture sessions per week. Effective Spring 2020 this course fulfills a single unit in each of the following BU Hub areas: Digital\/Multimedia Expression, Creativity\/Innovation, Research and Information Literacy.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">701<\/span><\/span> Advanced Mathematical Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY501) or equivalent. - Mathematical structures; algebraic systems, topological spaces, measure theory, and integration. Functional analysis: Banach and Hilbert spaces, linear functionals, operators, and spectral theory. Other applications at discretion of instructor.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">713<\/span><\/span> Quantum Field Theory 1<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY511 & CASPY512) - Provides an introduction to the techniques of quantum field theory with applications to high-energy and condensed-matter physics. Topics include field equations and quantization of many-body systems; Green function and linear response theory; S-matrix and scattering theory; path integration; perturbation expansions and the Feynman rules; renormalization and effective field theories; epsilon expansion and critical exponents.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">714<\/span><\/span> Quantum Field Theory 2<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (GRSPY713 & GRSPY751) or equivalent. - A continuation of GRS PY 713 for particle physicists. Topics include relativistic fields; LSZ formalism; the Lorentz group; quantum electrodynamics; non-Abelian gauge symmetry; spontaneous symmetry breaking; Goldstone's theorem; the Higgs mechanism; the Glashow-Weinberg-Salam model.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">731<\/span><\/span> Theory of Relativity<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY521 & CASPY522 & CASPY531) or consent of instructor. - An introduction to general relativity: the principle of equivalence; Riemannian geometry; Einstein's field equation; the Schwarzschild solution; the Newtonian limit; experimental tests; black holes; cosmology.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">741<\/span><\/span> Solid-State Physics I<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY511 & CASPY512 & CASPY541 & CASPY543) or equivalent. - One electron band structure: Formalism: Hartree-Fock, density functional frameworks. Methods: Green function, pseudopotentials and tight binding. Linear response. Optical properties. Elastic properties. Phonons: lattice dynamics and phenomenological methods. Electronic instabilities and transitions. Topological aspects of band structure and topological phases.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">742<\/span><\/span> Solid-State Physics II<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (GRSPY741) - Many-body formalism: second quantization, Green function, perturbation theory, Feynman diagrams. BEC and superfluidity. Fermi liquids; Luttinger liquids, bosonization. Electron-phonon interactions and superconductivity. Quantum magnetism: exchange mechanisms; magnetic insulators, spin-wave theory; itinerant magnetism, spin-density waves. Magnetic impurities, Anderson model, Kondo effect.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">743<\/span><\/span> Low-Temperature Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY512 & CASPY542) - Superconductivity, superfluidity, and properties of 3He and 4He at low temperatures. Techniques and measurement of physical quantities near absolute zero.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">744<\/span><\/span> Polymer Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY541 OR GRSCH653) and consent of instructor. - Introduction to polymer physics, focusing on the structure, phase behavior, and dynamics of isolated chains, polymer solutions, and gels. Development of underlying theoretical formalism and comparison with experimental results. Discussion of applications to novel polymeric materials. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">745<\/span><\/span> Experimental Surface Physics and Chemistry<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY543) or consent of instructor. - Introduction to the principles and experimental techniques of surface and interface physics and chemistry. Electronic, structural, vibrational, and magnetic properties of solid surfaces and interfaces. Emphasis on how these properties are measured. Also vacuum technology and x-ray generation.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">747<\/span><\/span> Advanced Statistical Mechanics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY501 & CASPY512 & CASPY531 & CASPY542) - Introduction to classical and quantum chaos: Random Matrix Theory. Eigenstate thermalization hypothesis. Doubly-stochastic evolution. Fluctuation theorems and other thermodynamic relations. Integrable systems, Many-body localization. Dynamics of Hamiltonian systems close to the adiabatic limit. Counter-adiabatic driving. Non-adiabatic response and quantum geometry.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">751<\/span><\/span> High-Energy Physics 1<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY511 & CASPY512) or consent of instructor. - Yearlong course (with GRS PY 752) on phenomenological aspects of modern high-energy physics. Principal topics are the standard model of strong and electro-weak interactions and the physics of electro-weak symmetry breaking. Intended for both theoretical and experimental students; emphasis on current calculational techniques.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">752<\/span><\/span> High-Energy Physics 2<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY511 & CASPY512) or consent of instructor. - Yearlong course (with GRS PY 751) on phenomenological aspects of modern high-energy physics. Principal topics are the standard model of strong and electro-weak interactions and the physics of electro-weak symmetry breaking. Intended for both theoretical and experimental students; emphasis on current calculational techniques.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">771<\/span><\/span> Systems Biology for Physical Scientists and Engineers<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (CASPY541 & CASPY571) or consent of instructor. - Focus is modern work on modeling biochemical networks. Core material includes signaling, genetic switches, biological oscillators and development. Begins with chemical kinetics in the context of molecular biology. Simple yet informative models based on physics approaches are emphasized.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">782<\/span><\/span> Advanced Materials Characterization<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Undergraduate Prerequisites: (CASPY543) or equivalent. - Introduction to the principles and applications of advanced materials characterization including study of atomic structure, electronic structure, defects, mechanical properties, transport properties, and carrier dynamics.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">789<\/span><\/span> Computational Quantum Many-Body Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">This course introduces computational techniques for lattice models of interacting fermions, bosons, and quantum spins. Methods include Lanczos diagonalization, matrix-product states, and quantum Monte Carlo methods. Applications are taken from condensed matter and quantum-device physics (e.g., quantum annealing).<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">811<\/span><\/span> Advanced Quantum Field Theory<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (GRSPY713) - Covers Scale Invariant Theories and Conformal Invariant Theories in various dimensions with applications to quantum criticality, statistical physics, and high-energy physics. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">841<\/span><\/span> Symmetry in Condensed Matter Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: (GRSPY741 & GRSPY742) or consent of instructor. - Theories of finite groups and their irreducible representations (Irreps), symmetry projection operators. Product groups and product representations. Crystalline symmetry, symmorphic and non-symmorphic space groups and induction of their Irreps. Spin-1\/2 double groups, magnetic color groups. Time-reversal symmetry and co-representations.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">895<\/span><\/span> Seminar: Special Topics in Theoretical Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">Var credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: consent of instructor. - Theoretical research topics include general relativity, quantum field theory, high energy and particle physics, phase transitions, renormalization group, laser physics, kinetic equations, biophysics, computational physics, and selected topics in mathematical physics. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">896<\/span><\/span> Seminar: Special Topics in Theoretical Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: consent of instructor. - Theoretical research topics include general relativity, quantum field theory, high energy and particle physics, phase transitions, renormalization group, laser physics, kinetic equations, biophysics, computational physics, and selected topics in mathematical physics. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">897<\/span><\/span> Seminar: Special Topics in Experimental Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Surface physics; intermediate energy nuclear physics experiments; low temperature techniques; liquid and solid helium; and magnetism at low temperatures. Raman effect, gels, and biophysics. High-energy physics experimental techniques.<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">898<\/span><\/span> Seminar: Special Topics in Experimental Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">4 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">Surface physics; intermediate energy nuclear physics experiments; low temperature techniques, liquid and solid helium, and magnetism at low temperatures. Raman effect, gels, and biophysics. High-energy physics experimental techniques. <\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">901<\/span><\/span> Research in Physics 1<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">Var credits.<\/span> <span class=\"cf-course-offered\">Fall<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">RES IN PHYS 1<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">901S<\/span><\/span> RES IN PHYS I<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">Var credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">RES IN PHYS 1<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">902<\/span><\/span> Research in Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">Var credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">RES IN PHYS 2<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">902S<\/span><\/span> RES IN PHYS II<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">Var credits.<\/span> <span class=\"cf-course-offered\"><\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">RES IN PHYS 2<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">903S<\/span><\/span> RES IN PHYS 3<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">Var credits.<\/span> <span class=\"cf-course-offered\">Summer<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">RES IN PHYS 3<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">909<\/span><\/span> Directed Study in Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">Var credits.<\/span> <span class=\"cf-course-offered\">Fall<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">DS IN PHYSICS 1<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">910<\/span><\/span> Directed Study in Physics<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">Var credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\">DS IN PHYSICS 2<\/p>\n\t<\/div>\n\n\t\n<\/aside><aside class=\"cf-course\">\n\t<div class=\"cf-course-card\">\n\t\t<h3 class=\"cf-course-title\"><span class=\"cf-course-id\"><span class=\"cf-course-college\">CAS<\/span> <span class=\"cf-course-dept\">PY<\/span> <span class=\"cf-course-number\">961<\/span><\/span> Scholarly Methods in Physics 1<\/h3>\n\t\t<p class=\"meta cf-course-info\"><span class=\"cf-course-credits\">1 credits.<\/span> <span class=\"cf-course-offered\">Fall and Spring<\/span> <span class=\"cf-course-prereqs\"><\/span><\/p>\n        \n\t\t<p class=\"cf-course-description\"> Graduate Prerequisites: graduate standing. - Introduction to scholarly methods in physics teaching and research: effective STEM instructional techniques; successful oral and written presentations; reading and reporting scientific literature; ethical obligations in physics teaching and research; career paths in physics. Required of first-semester doctoral students.<\/p>\n\t<\/div>\n\n\t\n<\/aside><div class=\"\"><span class=\"current\">1<\/span><\/div><\/div>\n","protected":false},"excerpt":{"rendered":"","protected":false},"author":1,"featured_media":0,"parent":22,"menu_order":3,"comment_status":"closed","ping_status":"closed","template":"","meta":[],"_links":{"self":[{"href":"https:\/\/www.bu.edu\/physics\/wp-json\/wp\/v2\/pages\/56"}],"collection":[{"href":"https:\/\/www.bu.edu\/physics\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/www.bu.edu\/physics\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/www.bu.edu\/physics\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/www.bu.edu\/physics\/wp-json\/wp\/v2\/comments?post=56"}],"version-history":[{"count":10,"href":"https:\/\/www.bu.edu\/physics\/wp-json\/wp\/v2\/pages\/56\/revisions"}],"predecessor-version":[{"id":4137,"href":"https:\/\/www.bu.edu\/physics\/wp-json\/wp\/v2\/pages\/56\/revisions\/4137"}],"up":[{"embeddable":true,"href":"https:\/\/www.bu.edu\/physics\/wp-json\/wp\/v2\/pages\/22"}],"wp:attachment":[{"href":"https:\/\/www.bu.edu\/physics\/wp-json\/wp\/v2\/media?parent=56"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}