The Department of Astronomy offers undergraduate and graduate instruction in a wide variety of fields, including theoretical and observational astrophysics; infrared, optical, and radio astronomy; galactic structure and dynamics of stellar systems; high-energy astrophysics and cosmology; star and planet formation; and spectroscopy. A considerable amount of research and teaching related to astronomy is done in other units at UC Berkeley, including the Physics Department, Earth and Planetary Science, Space Science Laboratory, and the Lawrence Berkeley National Laboratory. Various professors in the Chemistry, Mathematics, Statistics, and Engineering departments have an active interest in astronomy and are available for consultation.
Facilities
Many instruments are available to students and staff, including two 10-meter telescopes at the Keck Observatory on Mauna Kea in Hawaii; 30-inch, 40-inch and 120-inch telescopes at Lick Observatory; a 16-element millimeter-wave interferometer in Southern California; the PAPER Array in South Africa; and a 30-inch telescope at Leuschner Observatory (near the campus). Laboratories are available for the development of radio, infrared, and optical instruments and for the precise measurement of images and spectra. For further information regarding these resources, see the Facilities page on the department's website.
Physics-Astronomy Library
The Physics-Astronomy Library is located in 351 LeConte Hall. The Physics-Astronomy Library has approximately 95,000 volumes available (on campus and at the NRLF) and 700 journal subscriptions.
Astronomy Reading Room
The Astronomy Reading Room is located in 229 Campbell Hall and contains a selection of useful books and journals. For further information, see the Reading Room Catalog.
The Theoretical Astrophysics Center includes faculty, research scientists, postdoctoral researchers, and students working on a wide variety of problems in theoretical astrophysics.
The Center for Integrative Planetary Science is involved in many research projects including the ongoing Extrasolar Planet Search, astrobiology, and research into planetary composition and formation.
Terms offered: Fall 2015, Spring 2015, Spring 2014
Description of research and results in modern extragalactic astronomy and cosmology. We read the stories of discoveries of the principles of our Universe. Simple algebra is used. Introduction to Modern Cosmology: Read More [+]
Hours & Format
Fall and/or spring: 15 weeks - 2 hours of lecture per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Fall 2020, Fall 2019, Fall 2018
This is the first part of an overview of astrophysics, with an emphasis on the way in which physics is applied to astronomy. This course deals with the solar system and stars, while 7B covers galaxies and cosmology. Solar system topics include orbital mechanics, geology of terrestrial planets, planetary atmospheres, and the formation of the solar system. The study of stars will treat determination of observations, properties and stellar structure, and evolution. The physics in this course includes mechanics and gravitation; kinetic theory of gases; properties of radiation and radiative energy transport; quantum mechanics of photons, atoms, and electrons; and magnetic fields. Introduction to Astrophysics: Read More [+]
Rules & Requirements
Prerequisites: Math 1A -1B. Physics 5A, 5B/5BL or Physics 7A/B (5B or 7B can be taken concurrently)
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture and 1 hour of laboratory per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Spring 2020, Spring 2019, Spring 2018
This is the second part of an overview of astrophysics, which begins with 7A. This course covers the Milky Way galaxy, star formation and the interstellar medium, galaxies, black holes, quasars, dark matter, the expansion of the universe and its large-scale structure, and cosmology and the Big Bang. The physics in this course includes that used in 7A (mechanics and gravitation; kinetic theory of gases; properties of radiation and radiative energy transport; quantum mechanics of photons, atoms, and electrons; and magnetic fields) and adds the special and general theories of relativity. Introduction to Astrophysics: Read More [+]
Rules & Requirements
Prerequisites: Math 1A -1B. Physics 5A, 5B/5BL, 5C/5CL, or Physics 7A/B/C (5C or 7C can be taken concurrently)
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture and 1 hour of laboratory per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Summer 2020 First 6 Week Session, Summer 2020 Second 6 Week Session, Summer 2019 Second 6 Week Session
This seminar will explore one of a variety of subjects in greater depth than in introductory courses. Possible topics include stars, galaxies, the solar system, the interstellar medium, relativity and cosmology, history of astronomy, observational astronomy, and life in the universe. Selected Topics in Astronomy: Read More [+]
Rules & Requirements
Repeat rules: Course may be repeated for credit without restriction.
Hours & Format
Fall and/or spring: 15 weeks - 3-3 hours of lecture per week
Summer: 6 weeks - 7.5 hours of lecture per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Summer 2020 First 6 Week Session, Summer 2020 Second 6 Week Session, Summer 2019 Second 6 Week Session
A description of modern astronomy with emphasis on the structure and evolution of stars, galaxies, and the Universe. Additional topics optionally discussed include quasars, pulsars, black holes, and extraterrestrial communication, etc. Individual instructor's synopses available from the department. Introduction to General Astronomy: Read More [+]
Rules & Requirements
Credit Restrictions: Students will receive no credit for Astronomy 10 after taking Astronomy 7A or 7B, XAstronomy 10. Students can remove a deficient grade in XAstronomy 10 by taking Astronomy 10, Letter and Science C70U or Astronomy C10.
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture and 1 hour of discussion per week
Summer: 6 weeks - 8 hours of lecture and 2.5 hours of discussion per week 8 weeks - 6 hours of lecture and 2 hours of discussion per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Fall 2020, Fall 2019, Fall 2018
A description of modern astronomy with emphasis on the structure and evolution of stars, galaxies, and the Universe. Additional topics optionally discussed include quasars, pulsars, black holes, and extraterrestrial communication, etc. Individual instructor's synopses available from the department. Introduction to General Astronomy: Read More [+]
Rules & Requirements
Credit Restrictions: Students will receive no credit for 10 after taking 7A or 7B.
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture and 1 hour of discussion per week
Summer: 6 weeks - 8 hours of lecture and 2.5 hours of discussion per week 8 weeks - 6 hours of lecture and 2 hours of discussion per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Prior to 2007
The nature and evolution of the universe: history of astronomical knowledge; overall structure of the universe; galaxies, radio galaxies, peculiar galaxies, and quasars; structure and evolution of stars; exploding stars, pulsars, and black holes; exploration of the solar system; the search for extraterrestrial life. Introduction to General Astronomy: Read More [+]
Rules & Requirements
Prerequisites: High school algebra will be presumed but used sparingly
Credit Restrictions: Students will receive no credit for 10 after taking 7.
Hours & Format
Summer: 8 weeks - 6 hours of lecture per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Spring 2020, Spring 2019, Spring 2018
A tour of the mysteries and inner workings of our solar system. What are planets made of? Why do they orbit the sun the way they do? How do planets form, and what are they made of? Why do some bizarre moons have oceans, volcanoes, and ice floes? What makes the Earth hospitable for life? Is the Earth a common type of planet or some cosmic quirk? This course will introduce basic physics, chemistry, and math to understand planets, moons, rings, comets, asteroids, atmospheres, and oceans. Understanding other worlds will help us save our own planet and help us understand our place in the universe. The Planets: Read More [+]
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture and 1 hour of discussion per week
Summer: 6 weeks - 7.5 hours of lecture and 2.5 hours of discussion per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Summer 2020 8 Week Session, Summer 2019 8 Week Session, Summer 2018 8 Week Session
A tour of the mysteries and inner workings of our solar system. What are planets made of? Why do they orbit the sun the way they do? How do planets form, and what are they made of? Why do some bizarre moons have oceans, volcanoes, and ice floes? What makes the Earth hospitable for life? Is the Earth a common type of planet or some cosmic quirk? This course will introduce basic physics, chemistry, and math to understand planets, moons, rings, comets, asteroids, atmospheres, and oceans. Understanding other worlds will help us save our own planet and help us understand our place in the universe. This course is web-based. The Planets: Read More [+]
Hours & Format
Summer: 8 weeks - 6 hours of web-based lecture per week
Online: This is an online course.
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Instructor: Militzer
Formerly known as: Astronomy W12/Earth and Planetary Science W12
Terms offered: Fall 2018, Fall 2016, Fall 2014
This course will cover our modern scientific understanding of origins, from the Big Bang to the formation of planets like Earth, evolution by natural selection, the genetic basis of evolution, and the emergence of humans. These ideas are of great intrinsic scientific importance and also have far reaching implications for other aspects of people's lives (e.g., philosophical, religious, and political). A major theme will be the scientific method and how we know what we know. Origins: from the Big Bang to the Emergence of Humans: Read More [+]
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture and 2 hours of discussion per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Fall 2015, Fall 2011, Spring 2011
The Berkeley Seminar Program has been designed to provide new students with the opportunity to explore an intellectual topic with a faculty member in a small-seminar setting. Berkeley Seminars are offered in all campus departments, and topics vary from department to department and semester to semester. Freshman Seminars: Read More [+]
Rules & Requirements
Repeat rules: Course may be repeated for credit when topic changes.
Hours & Format
Fall and/or spring: 15 weeks - 1 hour of seminar per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: The grading option will be decided by the instructor when the class is offered. Final exam required.
Terms offered: Spring 2011, Spring 2008, Spring 2007
A small-size undergraduate seminar exploring one astronomical topic in depth. Students are responsible for much of the presentation. Seminar: Read More [+]
Hours & Format
Fall and/or spring: 15 weeks - 2 hours of seminar per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: The grading option will be decided by the instructor when the class is offered. Final exam required.
Terms offered: Spring 2020, Spring 2019, Spring 2017
Sophomore seminars are small interactive courses offered by faculty members in departments all across the campus. Sophomore seminars offer opportunity for close, regular intellectual contact between faculty members and students in the crucial second year. The topics vary from department to department and semester to semester. Enrollment limited to 15 sophomores. Sophomore Seminar: Read More [+]
Rules & Requirements
Prerequisites: At discretion of instructor
Repeat rules: Course may be repeated for credit when topic changes.
Hours & Format
Fall and/or spring: 5 weeks - 3-6 hours of seminar per week 10 weeks - 1.5-3 hours of seminar per week 15 weeks - 1-2 hours of seminar per week
Summer: 6 weeks - 2.5-5 hours of seminar per week 8 weeks - 1.5-3.5 hours of seminar and 2-4 hours of seminar per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: The grading option will be decided by the instructor when the class is offered. Final exam required.
Terms offered: Spring 2016, Spring 2015, Fall 2014
Supervised observational studies or directed reading for lower division students. Directed Study in Astronomy: Read More [+]
Rules & Requirements
Prerequisites: 7A-B, 10 and consent of instructor
Repeat rules: Course may be repeated for credit without restriction.
Hours & Format
Fall and/or spring: 15 weeks - 1-3 hours of independent study per week
Summer: 6 weeks - 2.5-7.5 hours of independent study per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Offered for pass/not pass grade only. Final exam not required.
Terms offered: Fall 2020, Fall 2019, Fall 2018
This course requires four to six experiments such as the following: accurate position and brightness measurements of stars; laboratory exploration of the characteristics of two-dimensional charge-coupled devices (CCDs) and infrared detectors; measurement of the distance, reddening, and age of a star cluster; measurement of the Stokes parameters and linear polarization of diffuse synchrotron and reflection nebulae; measurement of the period and pulse shape of the Crab pulsar using Fourier techniques. Professional telescopes will be used such as those at Leuschner Observatory and Lick Observatory. There is a emphasis on error analysis, software development in the IDL language, and high-quality written reports. Optical and Infrared Astronomy Laboratory: Read More [+]
Rules & Requirements
Prerequisites: Astronomy 7A-7B recommended; Mathematics 54 or Physics 89 (may be taken concurrently); Physics 7A-7B-7C (7C may be taken concurrently) or Physics 5A-5B-5C (5C may be taken concurrently)
Hours & Format
Fall and/or spring: 15 weeks - 4 hours of laboratory per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Spring 2020, Spring 2019, Spring 2018
Several basic laboratory experiments that concentrate on microwave electronics and techniques; construction of receiving, observing, and data analysis systems for two radioastronomical telescopes, a single-dish 21-cm line system and a 12-GHz interferometer; use of these telescopes for astronomical observing projects including structure of the Milky Way galaxy, precise position measurement of several radio sources, and measurement of the radio brightness distributions of the sun and moon with high angular resolution. There is a heavy emphasis on digital data acquisition, software development in the Python language, and high-quality written reports. Radio Astronomy Laboratory: Read More [+]
Rules & Requirements
Prerequisites: Astro 7A-7B recommended; Mathematics 53; Mathematics 54 or Physics 89; Physics 7A-7B-7C or Physics 5A-5B-5C
Hours & Format
Fall and/or spring: 15 weeks - 4 hours of discussion and 1 hour of lecture per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Spring 2020, Spring 2019
This course features 3 data-centric laboratory experiments that draw on a variety of tools used by professional astronomers. Students will learn to procure and clean data (drawn from a variety of world-class astronomical facilities), assess the fidelity/quality of data, build and apply models to describe data, learn statistical and computational techniques to analyze data (e.g., Bayesian inference, machine learning, parallel computing), and effectively communicate data and scientific results. There is a heavy emphasis on software development in the Python language, statistical techniques, and high-quality communication (e.g., written reports, oral presentations, and data visualization). Astronomy Data Science Laboratory: Read More [+]
Rules & Requirements
Prerequisites: Astro 7A-7B; Mathematics 53; Mathematics 54 or Physics 89; Astro 160; Astro C161 (may be taken concurrently) and Data C8 or C100 (or equivalent level of fluency of the Python programming language)
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of laboratory per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Alternate method of final assessment during regularly scheduled final exam group (e.g., presentation, final project, etc.).
Terms offered: Fall 2020, Fall 2019, Spring 2019
Topics covered include some, but not necessarily all, of the following. Observational constraints on the properties and evolution of stars. Theory of stellar structure and evolution. Stellar atmospheres and stellar spectroscopy. Stellar nucleosynthesis. Supernovae. Degeneracy of matter and structure of collapsed stars. Elements of gas dynamics, accretion onto compact objects, and x-ray sources. Dynamics and evolution of close binary systems. Stellar pulsation. Stellar Physics: Read More [+]
Rules & Requirements
Prerequisites: Astro 7A recommended; Physics 7A-7B-7C (7C may be taken concurrently) or Physics 5A-5B-5C (5C may be taken concurrently)
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture and 1 hour of discussion per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Terms offered: Spring 2020, Spring 2019, Spring 2018
Elements of general relativity. Physics of pulsars, cosmic rays, black holes. The cosmological distance scale, elementary cosmological models, properties of galaxies and quasars. The mass density and age of the universe. Evidence for dark matter and dark energy and concepts of the early universe and of galaxy formation. Reflections on astrophysics as a probe of the extrema of physics. Relativistic Astrophysics and Cosmology: Read More [+]
Rules & Requirements
Prerequisites: 110A-110B; 112 (may be taken concurrently)
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture and 1 hour of discussion per week
Additional Details
Subject/Course Level: Astronomy/Undergraduate
Grading/Final exam status: Letter grade. Final exam required.
Instructors: Boggs, Holzapfel, A. Lee, Ma, Quataert
Terms offered: Fall 2020, Fall 2019, Fall 2018
Physics of planetary systems, both solar and extra-solar. Star and planet formation, radioactive dating, small-body dynamics and interaction of radiation with matter, tides, planetary interiors, atmospheres, and magnetospheres. High-quality oral presentations may be required in addition to problem sets and a final exam. Planetary Astrophysics: Read More [+]
Terms offered: Spring 2012, Fall 2011, Fall 2010
An introduction to the basic physics of astronomy and astrophysics at the graduate level. Principles of energy transfer by radiation. Elements of classical and quantum theory of photon emission; bremsstrahlung, cyclotron and synchrotron radiation. Compton scattering, atomic, molecular and nuclear electromagnetic transitions. Collisional excitation of atoms, molecules and nuclei. Radiation Processes in Astronomy: Read More [+]
Rules & Requirements
Prerequisites: Physics 105, 110A; 110B concurrently; open to advanced undergraduates with GPA of 3.70
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture per week
Terms offered: Spring 2020, Spring 2019, Spring 2018
Principles of gas dynamics, self-gravitating fluids, magnetohydrodynamics and elementary kinetic theory. Aspects of convection, fluid oscillations, linear instabilities, spiral density waves, shock waves, turbulence, accretion disks, stellar winds, and jets. Astrophysical Fluid Dynamics: Read More [+]
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture per week
Terms offered: Spring 2019, Spring 2018, Spring 2017
Introduction to the flow of astronomical signals through telescope optics and into detectors; subsequent calibration, deconvolution of instrumental artifacts, and analysis. A broad wavelength approach is maintained with focus on shared fundamental concepts. Students "adopt a wavelength band" for assignments and presentations. Analysis and simulation of astronomical signals, noise, and errors. Astrophysical Techniques: Read More [+]
Rules & Requirements
Prerequisites: 201 and 290A; 290B must be taken concurrently
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture and 1 hour of laboratory per week
Terms offered: Fall 2011, Spring 2010, Spring 2008
Methods of data analysis, model fitting, and data display, all oriented towards the detailed analysis of astronomical observation data and/or numerical results from simulations. Specific topics include probability density functions, error propagation, maximum likelihood, least squares, data and function fitting, Fourier transforms, wavelets, principal components analysis, color images. The software language used is the Interactive Data Language (IDL). Numerical Techniques in Astronomy: Read More [+]
Rules & Requirements
Prerequisites: Mathematics 54
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of seminar per week
Terms offered: Fall 2020, Fall 2019, Fall 2018
An introduction to the basic physics of astronomy and astrophysics at the graduate level. Principles of energy transfer by radiation. Elements of classical and quantum theory of photon emission; bremsstrahlung, cyclotron and synchrotron radiation. Compton scattering, atomic, molecular and nuclear electromagnetic transitions. Collisional excitation of atoms, molecules and nuclei. Radiation Processes in Astronomy: Read More [+]
Rules & Requirements
Prerequisites: Physics 105, 110A; 110B concurrently; open to advanced undergraduates with GPA of 3.70
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture per week
Terms offered: Fall 2019, Spring 2018, Spring 2016
A basic course. Structure and kinematics of the galaxy; stellar population concepts; dynamics of stellar systems with and without encounters. Stellar Dynamics and Galactic Structure: Read More [+]
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture per week
Terms offered: Fall 2016, Fall 2015, Fall 2014
A survey of physical cosmology - the study of the origin, evolution, and fate of the universe. Topics include the Friedmann-Robertson-Walker model, thermal history and big bang nucleosynthesis, evidence and nature of dark matter and dark energy, the formation and growth of galaxies and large scale structure, the anisotropy of the cosmic microwave radiation, inflation in the early universe, tests of cosmological models, and current research areas. The course complements the material of Astronomy 218. Extragalactic Astronomy and Cosmology: Read More [+]
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture per week
Terms offered: Fall 2019, Fall 2018, Fall 2017
The physical foundations of planetary sciences. Topics include planetary interiors and surfaces, planetary atmospheres and magnetospheres, and smaller bodies in our solar system. The physical processes at work are developed in some detail, and an evolutionary picture for our solar system, and each class of objects, is developed. Some discussion of other (potential) planetary systems is also included. Solar System Astrophysics: Read More [+]
Rules & Requirements
Prerequisites: 149, 169, C160A or consent of instructor
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture per week
Terms offered: Spring 2020, Fall 2017, Fall 2015
Equations of stellar structure, radiative transfer and convection, thermonuclear reactions and stellar energy generations; stellar models, degenerate configurations, evolutionary sequences, supernovae, neutron stars, black holes, nucleosynthesis. Stellar Structure and Evolution: Read More [+]
Rules & Requirements
Prerequisites: Physics 110A-110B, 112, 137A-137B
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture per week
Terms offered: Fall 2018, Spring 2017, Spring 2014
Basic physics of high energy radiation processes in an astrophysics environment. Cosmic ray production and propagation. Applications selected from pulsars, x-ray sources, supernovae, interstellar medium, extragalactic radio sources, quasars, and big-bang cosmologies. High Energy Astrophysics: Read More [+]
Rules & Requirements
Prerequisites: 201 or consent of instructor. 202 recommended
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture per week
Terms offered: Spring 2020, Spring 2018, Spring 2016
A broad in-depth survey of state-of-the-art numerical approaches to astrophysical self-gravitational gas dynamics with application to large scale simulation of coupled non-linear astrophysical flows. Finite-difference approaches for Lagrangian and Eulerian astrophysical hydrodynamics and coupled radiation-hydrodynamics. N-body gravitation techniques including direct N-body, P-M, P3M, and hierarchical Tree. Particle gas dynamics methods such as smooth particle hydrodynamics (SPH), adaptive SPH and unification of SPH, and gravity tree hierarchies (TREE-SPH). Advanced techniques such as higher order Godunov finite difference methods with adaptive mesh refinement (AMR). Applications of these approaches in three broad areas: cosmology, high energy astrophysics, and star formation and the interstellar medium. Computational Methods in Theoretical Astrophysics: Read More [+]
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of lecture per week
Terms offered: Spring 2020, Spring 2019
This course features 3 data-centric laboratory experiments that draw on a variety of tools used by professional astronomers. PhD students will learn to procure and clean data (drawn from a variety of world-class astronomical facilities), assess the fidelity/quality of data, build and apply models to describe data, learn statistical and computational techniques to analyze data (e.g., Bayesian inference, machine learning, parallel computing), and effectively communicate data and scientific results. There is a heavy emphasis on software development in the Python language, statistical techniques, and high-quality communication (e.g., written reports, oral presentations, and data visualization). Astronomy Data Science Laboratory: Read More [+]
Rules & Requirements
Prerequisites: This class assumes that you have completed introductory astrophysical instruction (at the Astro 7A and 7B level) as well as knowledge of calculus (e.g. similar to Math 53) and linear algebra (e.g., similar to Math 54 or Physics 89).You should have proficiency or fluency in the Python programming language. This class heavily emphasizes software development, and is not the place to learn Python for the first time
Hours & Format
Fall and/or spring: 15 weeks - 3 hours of laboratory per week
Terms offered: Fall 2020, Spring 2020, Fall 2019
In addition to the weekly colloquium, the Department offers seminars in advanced topics, several of which are announced at the beginning of each semester. A maximum of 5 units may be taken per semester with a limitation of 2 in any one section. Seminar: Read More [+]
Rules & Requirements
Repeat rules: Course may be repeated for credit without restriction.
Hours & Format
Fall and/or spring: 15 weeks - 2 hours of seminar per week
Additional Details
Subject/Course Level: Astronomy/Graduate
Grading: Offered for satisfactory/unsatisfactory grade only.
Terms offered: Fall 2020, Spring 2020, Fall 2019, Fall 2018
The departments of Astronomy and Earth and Planetary Science offer a joint research seminar in advanced topics in planetary science, featuring speakers drawn from graduate students, postdoctoral researchers, faculty, and visiting scholars. Topics will span planetary interiors; surface morphology; atmospheres; dynamics; planet formation; and astrobiology. Speakers will vary from semester to semester. Meetings will be held once a week for 1 hour each, and the schedule of speakers will be determined on the first day of class. To pass the class, participants will be required to give a 30-minute presentation, either on their own research or on recent results from the literature. Planetary Science Seminar: Read More [+]
Rules & Requirements
Repeat rules: Course may be repeated for credit without restriction.
Hours & Format
Fall and/or spring: 15 weeks - 1-1 hours of seminar per week
Additional Details
Subject/Course Level: Astronomy/Graduate
Grading: Offered for satisfactory/unsatisfactory grade only.
Terms offered: Fall 2004, Fall 2003, Fall 2002
Open to a limited number of highly qualified undergraduate students interested in astronomy teaching at the college level. Students will participate in a seminar on educational methods and engage in tutorial or laboratory teaching under supervision of a faculty member. Undergraduate Astronomy Instruction: Read More [+]
Rules & Requirements
Prerequisites: An elementary astronomy course and consent of instructor
Repeat rules: Course may be repeated for credit up to a total of 4 units.
Hours & Format
Fall and/or spring: 15 weeks - 1 hour of lecture and 3-6 hours of laboratory per week
Additional Details
Subject/Course Level: Astronomy/Professional course for teachers or prospective teachers
Terms offered: Fall 2020, Fall 2019, Fall 2018
Discussion and practice of teaching techniques as applied to astronomy. Open to graduate students who are presently teaching assistants or associates. Two units for course plus one section; three units for two discussion sections. Instruction Techniques in General Astronomy: Read More [+]
Rules & Requirements
Prerequisites: Consent of instructor
Hours & Format
Fall and/or spring: 15 weeks - 2 hours of lecture per week
Additional Details
Subject/Course Level: Astronomy/Professional course for teachers or prospective teachers
Grading: Offered for satisfactory/unsatisfactory grade only.
Terms offered: Fall 2015, Fall 2014, Fall 2013
Individual study in consultation with the major field adviser, intended to provide an opportunity for qualified students to prepare themselves for the various examinations required of candidates for the Ph.D. (and other doctoral degrees). May not be used for unit or residence requirement for the doctoral degree. Individual Study for Doctoral Students: Read More [+]
Rules & Requirements
Repeat rules: Course may be repeated for credit without restriction.
Hours & Format
Fall and/or spring: 15 weeks - 1-8 hours of independent study per week
+ Indicates this faculty member is the recipient of the Distinguished Teaching Award.
Faculty
Steven Beckwith, Professor. Origins of life, cosmology, star formation, planet formation. Research Profile
Joshua Bloom, Professor. Machine learning, gamma-ray bursts, supernovae, time-domain astronomy, data-driven discovery. Research Profile
+ Eugene Chiang, Professor. Planetary science, theoretical astrophysics, dynamics, planet formation, circumstellar disks. Research Profile
Imke De Pater, Professor. Radio, planetary science, infrared, observations. Research Profile
Courtney Dressing, Assistant Professor. Searching for small, potentially habitable exoplanets orbiting nearby stars, characterizing planet host stars to improve stellar and planetary parameters, Investigating the dependence of planet occurrence on stellar and planetary properties. Research Profile
+ Alexei V. Filippenko, Professor. Supernovae, active galaxies, black holes, gamma-ray bursts, expansion of the universe. Research Profile
James R. Graham, Professor. Adaptive optics, infrared instrumentation, large telescopes. Research Profile
Raymond Jeanloz, Professor. Planetary geophysics, high-pressure physics, national and international security, science-based policy. Research Profile
Paul Kalas, Adjunct Professor. Planets, astronomy, Telescopes, Science Ethics. Research Profile
Daniel Kasen, Associate Professor. Theoretical and computational astrophysics. Research Profile
Richard I. Klein, Adjunct Professor. Astronomy, star formation, interstellar medium, coupled radiation-gas dynamical flows, supernova shockwaves, hydrodynamic collisions, high-energy astrophysics, photon bubble oscillations, hydro dynamics. Research Profile
Chung-Pei Ma, Professor. Astrophysics, dark matter, cosmology, formation and evolution of galaxies, cosmic microwave background radiation. Research Profile
Burkhard Militzer, Associate Professor. Saturn, structure and evolution of Jupiter, and extrasolar giant planets. Research Profile
Aaron Parsons, Assistant Professor. Radio astronomy instrumentation; cosmic reionization; digital signal processing; experimental cosmology; formation and evolution of large-scale cosmic structure (baryon acoustic oscillations and dark energy). Research Profile
Eliot Quataert, Professor. Compact objects, theoretical astrophysics, theoretical physics, black holes, accretion theory, plasma physics, high energy astrophysics, galaxies, stars. Research Profile
Uros Seljak, Professor. Theoretical, computational and data analysis in astrophysics and cosmology. Research Profile
Daniel R. Weisz, Assistant Professor. Near-field cosmology, galaxies, resolved stellar populations, stellar evolution, star formation, the stellar initial mass function. Research Profile
Martin White, Professor. Cosmology, formation of structure in the universe, dark energy, expansion of the universe, cosmic microwave background, quasars, redshift surveys. Research Profile
Jonathan Arons, Professor Emeritus. Astrophysics, compact astrophysical objects, Neutron Stars, ionized plasmas, cosmic rays, magnetized accretion disks, black holes pulsars, magnetic fields, planets. Research Profile
Gibor Basri, Professor Emeritus. Astronomy, low mass stars, brown dwarfs, star formation, T Tauri stars, stellar magnetic activity, starspots. Research Profile
Leo Blitz, Professor Emeritus. Astronomy, formation of galaxies, evolution of galaxies, conversion of interstellar gases, milky way, dark matter, dwarf galaxies, interstellar medium, high velocity clouds, hydrogen atom. Research Profile
C. Stuart Bowyer, Professor Emeritus. Space astrophysics. Research Profile
Marc Davis, Professor Emeritus. Astronomy, physical cosmology, large scale velocity fields, structure formation in the universe, maps of galactic dust. Research Profile
Reinhard Genzel, Professor Emeritus. Physics, existence and formation of black holes in galactic nuclei, the nature of the power source, the evolution of (ultra)luminous infrared galaxies, gas dynamics, the fueling of active galactic nuclei, the properties evolution of starburst galaxies. Research Profile
Carl E. Heiles, Professor Emeritus. Astronomy, interstellar medium, itsmorphology, supernovas, interstellar magnetic fields, Eridanus superbubble, interstellar gases. Research Profile
Christopher F. Mckee, Professor Emeritus. Astrophysics, interstellar medium, formation of stars, astrophysical fluid dynamics, computational astrophysics, astrophysical blast waves, supernova remnants, interstellar shocks. Research Profile
William J. (Jack) Welch, Professor Emeritus. Formation of stars, dark dust clouds, Michelson interferometer array, and Allen telescope array. Research Profile
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