About the author
Leslie M. Golden obtained his undergraduate education at Cornell University in engineering physics, with distinction, while working summers performing planetary exploration simulation studies at the AstroSciences Center of the Illinois Institute of Technology. At Cornell he worked with Bruce Hapke on characteristics of the lunar surface and studied under his early mentor, Frank Drake. His Ph.D was earned at the University of California, Berkeley, where he performed research in a variety of areas, working with Leland Cunningham on software for the determination of the orbits of comets, Carl Heiles on the definitive 21-cm map of the galaxy, Harold Weaver on selection effects in studying the evolution of quasars, and W.H. McCrea on isotropy of radio source counts with position over the sky. His dissertation, a microwave interferometric study of the subsurface of Mercury, was performed under William J. Welch with the prototype Hat Creek interferometer. It was cited as one of only two dissertations for excellence in the year of completion by the Berkeley chapter of Phi Beta Kappa. The models he devised form the basis for thermophysical models of planetary surfaces still currently employed.
Dr. Golden obtained a National Research Council grant and continued interferometric studies of Mercury at the Jet Propulsion Laboratory and as a consultant at the Aerospace Corporation before receiving his academic appointment at the University of Illinois at Chicago.
Writing and public speaking allow Dr. Golden to share his enthusiasm. In addition to numerous technical articles, he was the award winning editor-in-chief of the Cornell Engineer magazine, and won the senior division of the Nicolaus Copernicus 500th Anniversary science-writing competition, the Eric Hoffer-Lili Fabilli Essay Award, and an award in the Griffith Observatory Science Writing Contest.
In demand as an authoritative and entertaining public speaker and lecturer, Dr. Golden, among many engagements, was selected by Royal Cruise Lines to be their on-board lecturer on the high seas during the 1986 apparition of Halley’s Comet, addressed the Adler Planetarium as the keynote speaker during the opening of their new wing, provided a lecture series on extraterrestrial life to the Field Museum of Natural History, and has been the only University of Illinois professor to be selected as a visiting faculty member on Semester at Sea through the University of Pittsburgh. He speaks widely to library, school, youth, and adult groups on various topics in astronomy.
Dr. Golden is one of a handful of individuals who is a member of both Tau Beta Pi, the engineering honorary society, and Phi Beta Kappa, the arts and sciences honorary society. He was also elected to Pi Delta Epsilon, the honorary journalism society.
This book presents experiments which will teach physics relevant to astronomy. The astronomer, as instructor, frequently faces this need when his college or university has no astronomy department and any astronomy course is taught in the physics department. The physicist, as instructor, will find this intellectually appealing when faced with teaching an introductory astronomy course. From these experiments, the student will acquire important analytical tools, learn physics appropriate to astronomy, and experience instrument calibration and the direct gathering and analysis of data. Experiments that can be performed in one laboratory session as well as semester-long observation projects are included.
Springer New York
; November 2012
585 pages; ISBN 9781461433118Read online
, or download in secure PDF format
Title: Laboratory Experiments in Physics for Modern Astronomy
Author: Leslie M. Golden
PART I TOOLS OF THE ASTRONOMER.- Introduction.- A Review of Mathematical Concepts and Tools .- A Review of Graphing Techniques .- The Optics of Telescopes, I. Image Size and Brightness.- The Optics of Telescopes, II. Magnification and Chromatic Aberration.- PART II. THE SOLAR SYSTEM.- Introduction.- Earth, The Seasons and Local Latitude.- The Surface Roughness of the Moon, Reflection and Scattering from a Planetary Surface I. Surface Materials.- The Surface Roughness of the Moon, Reflection and Scattering from a Planetary Surface II. Beads and Surface Coverage.- The Formation of Impact Craters.- Determination of the Rotation Rate of Planets and Asteroids by Radar, I. Observations of Mercury .- Determination of the Rotation Rate of Planets and Asteroids by Radar, II. Observations of Simulated Planets.- The Orbit of Venus.- Kepler's Laws of Planetary Motion .- The Galilean Satellites of Jupiter .- Thermal Radiation from a Planetary Subsurface, I. Calibration and Initial Measurements .- Thermal Radiation from a Planetary Subsurface, II. Soil Sample Measurements.- The Microwave Phase Effect of the Moon .- PART III. MEASURING THE STARS AND BEYOND.- Introduction.- Blackbody Radiation .- The Surface Temperature and Energy Output of the Sun.- The Theory of Atomic Spectra: The Balmer Lines .- Discovering the Nature of Objects in Space: Kirchhoff's Laws of Radiation.- Appendices.- Index