Astronomy 2. Celestial Navigation
Catalog Number: 2179 Enrollment: Limited to 30.
Philip M. Sadler and assistants
Half course (spring term). Tu., 11:30–1:30 and 7–10 p.m. EXAM GROUP: 13, 14
Never be lost again! Find your way on sea, land, or air by employing celestial and terrestrial techniques. Acquire expertise in using navigators’ tools (sextant, compass, and charts) while learning the steps to the celestial dance of the Sun, Moon, stars, and planets. This 107-year-old course continues to rely on practical skills and collaborative problem-solving, while utilizing historical artifacts (instruments, maps, captains’ logs) and student-built devices.
Note: Minimum lecturing; predominantly practical laboratory activities with individual attention from teaching staff. Math beyond high school trigonometry and geometry unnecessary. Some familiarity with sailing and/or astronomy is helpful.
Astronomy 45. Introduction to Astrophysics
Catalog Number: 5375
Alexander Dalgarno
Half course (fall term). M., W., F., at 10. EXAM GROUP: 3
An introduction to the concepts and methods of astrophysics, including a discussion of astronomical measurements and stellar magnitudes, and a systematic account of the astrophysical nature of radiation, planetary motion, tidal interactions, binary stars, galactic dynamics and cosmology.
Prerequisite: Physics 15a,b (Physics 15b may be taken concurrently).
*Astronomy 91r. Supervised Reading and Research
Catalog Number: 1545
Jonathan E. Grindlay and members of the Department
Half course (fall term; repeated spring term). Hours to be arranged.
Supervised reading and research in subjects not normally included in the regular course offerings of the department.
Note: Students must arrange for course supervision with an individual member of the department. The course may not be counted for the concentration requirements except by special permission and may not be taken more than twice.
*Astronomy 97hf. Introductory Tutorial
Catalog Number: 6604
Robert W. Noyes and members of the Department
Half course (throughout the year). F., 2–4.
Introduction to methods of problem solving in astrophysics. Contact with Department of Astronomy faculty and their research programs. Students meet in small groups with a faculty member for two weeks to work through a problem as an introduction to astronomical questions and research methods. Through the year, each student meets with approximately 10 members of the department.
Note: Open to sophomore concentrators and others (including freshmen with a high school physics background) considering the concentration or a combined concentration.
Prerequisite: Physics 15a,b or equivalent (can be taken concurrently).
*Astronomy 98hf. Tutorial — Junior Year
Catalog Number: 3121
Ramesh Narayan and members of the Department
Half course (throughout the year). W., 2–4.
Note: Normally a required course for junior concentrators in Astronomy. Open in special cases to concentrators in other physical sciences. Weekly lectures, assigned reading, and discussion meetings during the fall term, individually supervised program of reading and research leading to a paper and lecture on a chosen topic during the spring term.
*Astronomy 99. Tutorial — Senior Year
Catalog Number: 5413
Ramesh Narayan and members of the Department
Full course. 1st meeting required W., 2-4. Other hours to be arranged.
Note: For honors candidates in Astronomy. Individually supervised reading and research leading to the honors thesis.
Prerequisite: Astronomy 98hf.
Astronomy 145. Topics in Astrophysics
Catalog Number: 0212
John P. Huchra
Half course (spring term). M., W., 9:30–11. EXAM GROUP: 2, 3
Discussion of a wide range of astrophysical systems, their physical processes, and observed characteristics. Topics include the Big Bang, the microwave background, the formation of structure in the universe, galaxy formation and evolution, star formation, energy generation in stars, white dwarfs, neutron stars, and black holes.
Prerequisite: Physics 143a (may be taken concurrently).
Astronomy 150. Radiative Processes in Astrophysics
Catalog Number: 8993
George B. Rybicki
Half course (fall term). M., W., 10–11:30. EXAM GROUP: 3, 4
Survey of radiative processes of astrophysical importance from radio waves to gamma rays. Thermal and non-thermal processes, including bremsstrahlung, synchrotron radiation, and Compton scattering. Radiation in plasmas. Atomic and molecular structure and spectra.
Prerequisite: Physics 143a (may be taken concurrently).
Astronomy 191. Astrophysics Laboratory
Catalog Number: 3615 Enrollment: Limited to 16.
Patrick Thaddeus and Jonathan E. Grindlay
Half course (spring term). Th., at 2. First class meeting will be Friday, January 31 from 2-4 in the Pratt Conference room at the Observatory. EXAM GROUP: 16
Laboratory and observational projects in astrophysics. Students choose two projects from a selection including: measurement of the temperature of the cosmic microwave background radiation; observations of dense interstellar clouds; various projects with the Very Large Array; measurement of the rotation of the Galaxy with the CFA millimeter-wave telescope; development of superconducting submillimeter detectors; spectroscopy of binary stars; photometry and spectroscopy of star clusters; principles of soft x-ray detectors, and development of hard x-ray imaging detectors and telescopes.
Note: Intended primarily for concentrators in Astronomy and Astrophysics or combined concentrators with Physics. Students with Physics as their primary concentration, but with a serious interest in astrophysics, may take this to satisfy their laboratory requirement (in lieu of Physics 191) upon petition to the Head Tutor in Physics.
Prerequisite: Physics 15c or equivalent.
[Astronomy 192. Tools and Techniques of Astronomical Measurements]
Catalog Number: 4741
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Half course (spring term). Hours to be arranged.
Presentation of physical principles and techniques used for detection across the frequency domain of both electromagnetic and gravitational radiation. Description and analysis of the corresponding tools used for detection, including telescopes and basic instrumentation, present and (near-term) future. Discussion of different types of measurements—intensity, imaging, spectroscopic, polarimetric, astrometric, and interferometric—throughout the electromagnetic spectrum, including related parameter estimation and error analyses.
Note: Expected to be given in 2003–04.
Prerequisite: Physics 15a,b,c and Applied Mathematics 105 (or equivalents).
Astronomy 193. Noise and Data Analysis in Astrophysics
Catalog Number: 4495
James M. Moran
Half course (fall term). Tu., Th., at 2. EXAM GROUP: 16
How to design experiments and get the most information from noisy, incomplete, flawed, and biased data sets. Basics of probability theory; Bernouli trials; Bayes theorem; random variables; distributions; functions of random variables; moments and characteristic functions; Fourier transform analysis; Stochastic processes; estimation of power spectra. Digital data processing: sampling theorem, filtering; fast Fourier tranform; spectrum of quantized data sets. Weighted least mean squares analysis and nonlinear parameter estimation. Noise processes in periodic phenomena. Image processing and restoration techinques.
Prerequisite: Mathematics 21b or equivalent.
[*Astronomy 204. Galactic and Extragalactic Dynamics]
Catalog Number: 6396
Matthew Holman
Half course (spring term). Hours to be arranged.
Review of Lagrangian and Hamiltonian dynamics. Dynamics of stellar systems. Properties of orbits. The collisionless Boltzmann equation and Jeans theorem. Models for star clusters, galaxies, and clusters of galaxies. The evolution of globular clusters. Dynamical friction, tides, mergers, and cannibalism. Density wave theory of spiral structure. Formation of galaxies. Simulation of galaxy dynamics. Applications to planetary systems.
Note: Expected to be given in 2003–04.
Prerequisite: Physics 151 or equivalent.
Astronomy 206. Stellar Physics
Catalog Number: 2128
Dimitar D. Sasselov
Half course (fall term). Tu., Th., 10–11:30. EXAM GROUP: 12, 13
Stellar physics is studied from two basic precepts: of stars as the elementary (baryonic) building blocks in the Universe and of the evolution of matter (nucleosynthesis). The theory of stellar interiors and atmospheres is developed from general grounds and applied as fit to the variety of stellar objects and their environments.
[Astronomy 207. Cosmology and Extragalactic Astronomy]
Catalog Number: 2446
Lars Hernquist
Half course (spring term). Hours to be arranged.
The cosmological principle: isotropy and homogeneity, cosmological world models, thermal history of the Big Bang, the microwave background, growth of density fluctuations, formation and evolution of galaxies, active galactic nuclei, large scale structure, structure of galaxies and clusters of galaxies, gravitational lensing, candidates for dark matter, measurements of cosmological parameters.
Note: Expected to be given in 2003–04.
Astronomy 208. The Physics of the Interstellar Medium
Catalog Number: 4842
Bryan M. Gaensler
Half course (spring term). Tu., Th., 10–11:30. EXAM GROUP: 12, 13
Physical processes in the interstellar medium of the Milky Way and other galaxies. Line and continuum processes, excitation, ionization, dissociation, heating and cooling, neutral clouds, ionized gas, photo-ionized nebulae, molecular clouds, star forming regions, shocks, gas dynamics, magnetic fields, supernova remnants, dust.
[Astronomy 218. Radio Astronomy]
Catalog Number: 2883
James M. Moran
Half course (fall term). Hours to be arranged.
Historical development; theory of antennas and interferometers; signal detection and measurement techniques. Thermal, synchrotron and spectral-line emission in the context of radio observations of the sun, planets, pulsars, masers, hydrogen clouds, molecular clouds, ionized regions, active galaxies, quasars, and the cosmic background.
Note: Expected to be given in 2003–04.
Prerequisite: Astronomy 150 or Physics 153 recommended.
Astronomy 219. High Energy Astrophysics
Catalog Number: 1858
Jonathan E. Grindlay and Ramesh Narayan
Half course (spring term). Tu., Th., 2–3:30. EXAM GROUP: 16, 17
Discussion of relativistic and high-energy astrophysical phenomena. Accretion disks and magnetic accretion. Compact stars: white dwarfs, neutron stars, black holes. Binary evolution. Cosmic ray and gamma-ray astronomy, observational techniques and sources, gamma-ray bursts and jets. X-ray astronomy, detectors, telescopes, and analysis techniques. X-ray sources, accreting x-ray binaries: bursts, disk coronae, supernova remnants, galaxy clusters. Active galactic nuclei and super-massive black holes. X-ray and gamma-ray background.
[Astronomy 225. Formation of Stars and Planets]
Catalog Number: 0983
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Half course (fall term). Hours to be arranged.
Physical properties of the interstellar medium, molecular clouds and their cores, young stellar objects in isolation and in clusters, dynamical processes in star formation and circumstellar disk evolution, properties of the primitive solar nebula and solar system development, extrasolar planetary systems.
Note: Expected to be given in 2003–04.
*Astronomy 302. Scientists Teaching Science
Catalog Number: 9869
Philip M. Sadler 2231
Half course (fall term). Tu., 2–3:30. EXAM GROUP: 16, 17
Learn the secrets of lecturing well, leading discussions, connecting to real-world applications, and creating tests in any scientific discipline as we focus on relevant educational research and case studies, plus engage in practical classroom activities.
Note: This course is open to graduate students in all areas of science and will use activities and draw upon research findings from the life, earth, and physical sciences.
Prerequisite: Experience as an instructor of science or as a teaching fellow.