Edwin F. Taylor | |
---|---|
Born | [1] Oberlin, Ohio, U.S. | June 22, 1931
Nationality | American |
Awards | Oersted Medal (1998) |
Scientific career | |
Fields | Physics Education |
Institutions | Wesleyan University Massachusetts Institute of Technology Boston University Carnegie Mellon University |
Doctoral advisor | Nicolaas Bloembergen |
Website | eftaylor.com |
Edwin Floriman Taylor (born June 22, 1931) is an American physicist known for his contributions to the teaching of physics. Taylor was editor of the American Journal of Physics , and is author of several introductory books to physics. In 1998 he was awarded the Oersted Medal for his contributions to the teaching of physics.
Edwin Floriman Taylor was born in Oberlin, Ohio on June 22, 1931, as was the son of Lloyd William Taylor, chairman of the Oberlin College physics department from 1924 to 1948, and Esther Bliss Taylor. [2]
Taylor completed an A.B. degree at Oberlin College in 1953 and obtained first a master (1954) and later a Ph.D. (1958) in physics at Harvard University, where his advisor was Nicolaas Bloembergen. After employment at Wesleyan University as an assistant professor of physics, Taylor moved to the Education Research Center at the Massachusetts Institute of Technology, where Taylor he remained for 25 years, first as a Visiting Associate Professor and later as a senior research scientist. [3] [1]
After retiring from MIT in 1991, Taylor went on to positions first at Boston University and then at Carnegie Mellon University. He served as editor of the American Journal of Physics from 1973 to 1978. [3] [1]
Taylor’s primary research interests are in the field of physics education. One of his areas of activity was curriculum development: he was part of the team gathered by Jerrold Zacharias to develop a new undergraduate physics course at MIT, was a member of the steering committee of the Introductory University Physics Project (IUPP) for several years, and was involved in developing high school physics curricula at Boston University. [3]
Through his physics text books, Taylor became known to a wider academic audience. During a Junior Faculty Sabbatical at Wesleyan University, which Taylor spent at Princeton University, he collaborated with the relativist John Archibald Wheeler on an introductory text on special relativity, which began with Wheeler's relativity lectures to an honors physics freshman class, which Taylor transcribed, and evolved into an intense collaboration that resulted in the book Spacetime Physics, published in 1965. [4]
Taylor and Wheeler later resumed their collaboration to produce an introduction to general relativity, published in 2000 as Exploring Black Holes. The book presents fundamental ideas from the theory, using no more than basic differential and integral calculus. Specific aspects of relativity are explored in "project" chapters interspersed throughout the main text. [5]
Together with the British physicist and physics educator Anthony French, Taylor wrote the undergraduate text book An Introduction to Quantum Physics, first published in 1979.
Taylor was also a pioneer in using both computers in general and the internet in particular as teaching tools. To this end, he co-developed software designed to help students understand the geometry and the effects of special relativity, [6] and taught an early online course offered by Montana State University. [3]
In 1998, Taylor received the Oersted Medal from the "For his profound contributions to the pedagogy of relativity and quantum mechanics, his service to the physics community as editor of the American Journal of Physics, and his pioneering efforts in the development of software for relativity, quantum mechanics, and Internet teaching." [3]
A full, free download of the second edition of Taylor and Wheeler's special relativity text is available at spacetimephysics.org. A second edition of the general relativity text was prepared with Edmund Bertschinger, and is available only in online form for full and free download at exploringblackholes.org.
Template:FgShort description
Quantum gravity (QG) is a field of theoretical physics that seeks to describe gravity according to the principles of quantum mechanics. It deals with environments in which neither gravitational nor quantum effects can be ignored, such as in the vicinity of black holes or similar compact astrophysical objects, such as neutron stars as well as in the early stages of the universe moments after the Big Bang.
The theory of relativity usually encompasses two interrelated physics theories by Albert Einstein: special relativity and general relativity, proposed and published in 1905 and 1915, respectively. Special relativity applies to all physical phenomena in the absence of gravity. General relativity explains the law of gravitation and its relation to the forces of nature. It applies to the cosmological and astrophysical realm, including astronomy.
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