103 Astronomy (3:3:0) Not for physics majors. Introduction to origin of life, Earth, planets and sun, stars, galaxies, quasars, nature of space radiation, and general theory of relativity.
111 Introductory Astronomy: The Solar System (3:3:0) ASTR 111 and 112 can be used to fulfill a 4-credit lab science requirement; not for physics majors. Topics include history of astronomy, evolution of the solar system, properties of planets, scientific method, critical thinking, nature of light, and principles of telescope design.
112 Introductory Astronomy Lab: The Solar System (1:0:3) Laboratory course associated with ASTR 111. ASTR 111 and 112 can be used to fulfill a 4-credit lab science requirement; not for physics majors.
113 Introductory Astronomy: Stars, Galaxies, and the Universe (3:3:0) ASTR 113 and 114 can be used to fulfill a 4-credit lab science requirement; not for physics majors. Topics include electromagnetic radiation, stellar evolution, interstellar medium, galaxies, cosmology, scientific method, and critical thinking.
114 Introductory Astronomy Lab: Stars, Galaxies, and the Universe (1:0:3) Laboratory course associated with ASTR 113. ASTR 113 and 114 can be used to fulfill a 4-credit lab science requirement; not for physics majors.
301 Astrobiology (3:3:0) Prerequisites: MATH 113 and PHYS 160. Physical science perspective on origin and evolution of life on Earth and how life, in turn, has significantly influenced Earth’s evolution. Topics include origin of Earth, mechanisms and sites for origin of life, coevolution of life and Earth’s atmosphere, habitability of planets, and search for extraterrestrial life.
302 Foundations of Cosmological Thought (3:3:0) Examines scientific, historical, and philosophical foundations and development of cosmological thought from antiquity to the present. Emphasizes qualitative understanding of the development of cosmology concluding with the present concept of origin and evolution of universe. No advanced background in mathematics or natural sciences required.
328/PHYS 328 Introduction to Astrophysics (3:3:0) Prerequisites: PHYS 262 and MATH 214. Topics include physical concepts; magnitudes of stars; Hertzsprung-Russell diagram; stellar radiation; stellar structure and evolution; white dwarfs, red giants, supernovas, neutron stars, and black holes; interstellar matter, dust, and molecules; cosmic rays and magnetic fields; galactic structure, galaxies, quasars, and intergalactic matter; high energy astrophysics, cosmology and general relativity; and models of the universe.
390 Topics in Astronomy (1–4:1–4:0) Selected topics not covered in fixed content courses. May not be included for credit by physics majors in the 45 credits of physics courses required for BS degree, or in 31 credits of physics courses required for BA degree.
401 Computer Simulation in Astronomy (3:3:0) Prerequisites: MATH 213 and ASTR 328. Techniques and methods to simulate astronomical phenomena using a computer. Examples taken from a wide variety of astronomical phenomena, including radiation transfer in astrophysical objects, self-gravitating systems, hydrodynamics, and stellar models. Emphasizes hands-on projects.
402 Methods of Observational Astronomy (3:3:0) Prerequisites: ASTR 111, 112, 113, 114. Collection and analysis of data covering radio, microwave, infrared, visible, ultraviolet, X-ray, and gamma ray astronomy. Topics include electromagnetic spectrum, coordinate systems, motion of celestial objects, telescopes, detectors, statistics, and noise, interferometry, and spectroscopy. This course meets the writing intensive requirement.
403 Planetary Sciences (3:3:0) Prerequisites: MATH 213 and PHYS 160. Introduction to the physics and chemistry of planets and their natural satellites, asteroids, and comets. Topics include history of the solar system; origin and evolution of planets, their internal structure and atmospheres; and analytical techniques used in remote and in situ study.
404 Galactic Astronomy (3:3:0) Prerequisites: MATH 214, ASTR 328, and PHYS 308. Comprehensive introduction to observational and theoretical aspects of the study of galaxies. Topics include our own galaxy, normal galaxies and their hierarchical structures (groups and clusters), star forming and active galaxies, and colliding galaxies.
408 Senior Research (3:3:0) Prerequisites: 15 credits of ASTR courses. Students may not receive more than 6 credits of ASTR 408 and 409. Independent work under guidance of faculty member on research project in experimental, observational, or theoretical astronomy. Written report on project required. May be taken twice with department permission.
409 Astronomy Internship (3:3:0) Prerequisites: 75 credits, 15 ASTR credits, and permission of department. See department for other requirements and application procedure prior to enrollment. Students may not receive more than 6 credits of ASTR 408 and 409. On-the-job experience for astronomy majors in industry or government laboratories, including summer research programs. Students work in observational, experimental, or theoretical astronomy, and prepare written report at end of internship.
428/PHYS 428 Relativity and Cosmology (3:3:0) Prerequisite: MATH 214; PHYS 303, 305, and 262; or permission of instructor. Special relativity; four-dimensional space-time; general relativity; non-Euclidean geometries, geodesics, and field equations; tests of general theory of relativity; black holes; cosmology; models of the universe; remnant blackbody radiation; big bang cosmology; thermodynamics; and the universe.
490 Astronomy Capstone (3:3:0) Prerequisites: completion of ASTR core courses or concurrent enrollment in final core courses. Capstone course providing a learning experience, integrating knowledge from previous astronomy courses with selected readings from current scientific papers and an opportunity to effectively present that synthesis. Emphasizes student participation and student-led class discussions. Required of all astronomy majors.
530/CSI 661 Astrophysics (3:3:0) Prerequisites: PHYS 303, 305, 308; MATH 214. Survey of contemporary astrophysics. Topics include physical concepts, stellar spectra, Hertzsprung-Russell diagram, stellar atmospheres, stellar structure, interstellar matter, stellar evolution, high-energy phenomena, hydrodynamical processes in astrophysics, accretion disk formation, and shock formation.
535/CSI 660 Space Instrumentation and Exploration (3:3:0) Prerequisites: PHYS 262 and MATH 213. Survey of instruments, devices, and methods for space and planetary exploration, including remote sensing of Earth and other solar system bodies, and planned manned and unmanned missions by the United States and other countries.
590 Selected Topics in Astronomy and Astrophysics (1–6:0–6:0) Advanced topics from recent theoretical or observational developments and their applications. Satisfies needs of professional community to keep abreast of current developments.
680 Physics of Interstellar Media (3:3:0) Prerequisites: PHYS 402 or permission of instructor. Physical processes in the interstellar media. Topics include the production and transfer of radiation, ionization and recombination, atomic and molecular excitation, dust physics, gas heating and cooling, and star formation.
703 Planetary Sciences (3:3:0) Prerequisites: MATH 213 and PHYS 160. This course will cover the processes and events that have played a central role in the origin and evolution of the solar system, with special emphasis on the terrestrial planets. The unique history of Earth and how it has evolved into a habitable world will be covered in detail.
704 Galactic Astronomy (3:3:0) Prerequisites: MATH 214, ASTR 328, and PHYS 308. Comprehensive introduction to observational and theoretical aspects of the study of galaxies. Topics include our own galaxy, normal galaxies and their hierarchical structures (groups and clusters), star forming and active galaxies, and colliding galaxies.
760/PHYS 760 Space Plasma Physics (3:3:0). Prerequisite: PHYS 622 or 513, or permission of instructor. Covers plasma processes involved in today’s space physics research, including different regimes of plasma; basic concepts in kinetic, fluid, and MHD plasmas; and existent waves in these media. Also covers basics of shocks, discontinuities, transport and acceleration of particles such as cosmic rays, reconnection, and MHD instabilities.
761/CSI 761 N-Body Methods and Particle Simulations (3:3:0) Prerequisites: PHYS 613 and CSI 717, or permission of instructor. Study of particle methods as a tool to solve variety of physical systems. Emphasizes study and development of numerical results, and visualization of these results in complex physical systems. Applications and projects include stellar and galaxy dynamics, smoothed particle hydrodynamics, plasma simulations, and semiconductor device theory. Includes algorithms on parallel and vectorized systems.
764/CSI 764 Computational Astrophysics (3:3:0) Prerequisite:ASTR 530 or permission of instructor. Study of statistical mechanics concepts important in astrophysics. Presentation of unified approach to particle acceleration and interaction theory based on analytical and numerical analysis of Boltzmann and Liouville equations. Discussion of computational methods relevant for particle transport problems, with emphasis on Fokker-Planck and Monte-Carlo solution techniques. Applications from space sciences include studies of cosmic ray acceleration, photon comptonization, particle transport in the near-Earth environment, energy transport in stellar atmospheres, and self-gravitating system dynamics.
765/CSI 765 High-Energy and Accretion Astrophysics (3:3:0) Prerequisites: PHYS 502 and 513, and ASTR 530; or permission of instructor. Overview of the field of atomic and nuclear physics, including nuclear reactions of use to high-energy astrophysics. Discusses radiation processes in cosmic plasmas emphasizing quantum mechanical calculations; stellar evolution and nucleosynthesis; computational models of stellar evolution; binary stars and accretion disks; numerical models of the structure of accretion disks; compact stars, white dwarfs, neutron stars, and black holes; acceleration processes and cosmic rays; interstellar medium and propagation of cosmic rays; high-energy processes in the center of galaxies; and ground- and space-based techniques and observations.
766/CSI 766 Relativity and Cosmology (3:3:0) Prerequisites: ASTR 530 and MATH 314, or permission of instructor. Special relativity, four-dimensional space-time, general relativity, non-Euclidean geometries, geodesic and field equations, test of general relativity theory, black holes, cosmic background radiation, thermodynamic considerations in cosmology, and cosmological models.
769/CSI 769 Topics in Space Sciences (3:3:0) Prerequisite: permission of instructor. Selected topics in space sciences not covered in fixed-content space sciences courses. May be repeated for credit as needed.
790 Advanced Topics in Astronomy and Astrophysics (1–6:0–6:0) Prerequisite: graduate standing and permission of instructor. Advanced topics from recent theoretical or observational developments and applications. Satisfies need of professional community to keep abreast of current developments.
796 Directed Reading and Research (1–6:0:0) Prerequisite: admission to master’s program and permission of instructor. Reading and research on a specific topic in astronomy, astrophysics, or related field under direction of faculty member. May be repeated as needed.
798 Research Project (3:0:0) Prerequisite: 9 credits and permission of instructor. Research project chosen and completed under guidance of graduate faculty member resulting in an acceptable technical report. May not be repeated.
799 Master’s Thesis (1–6:0:0) Prerequisite: 9 credits, and permission of instructor. Research project chosen and completed under guidance of graduate faculty member resulting in acceptable technical report and oral defense acceptable to three-faculty-member thesis committee. May not be repeated.
998 Doctoral Dissertation Proposal (1–12:0:0) Prerequisites: admission to physics doctoral program and permission of advisor. Covers development of a research proposal under the guidance of a dissertation director and the doctoral committee. The proposal forms the basis for the doctoral dissertation. May be repeated as needed; however, no more than 24 credits in ASTR/PHYS 998 and ASTR/PHYS 999 may be applied toward satisfying doctoral degree requirements in the physics PhD program. Out of the 24, no more than 12 credits of ASTR/PHYS 998 may be applied.
999 Doctoral Dissertation (1–12:0:0) Prerequisite: admission to doctoral candidacy in physics doctoral program and permission of advisor. Doctoral research performed under direction of dissertation director. May be repeated as needed; however, no more than 24 credits in ASTR/PHYS 998 and ASTR/PHYS 999 may be applied toward satisfying doctoral degree requirements in the physics PhD program.