User talk:Bradley Goldsmith
This user is a student editor in University_of_Chicago/Science,_Culture_and_Society_III_(Winter) . |
Bradley Goldsmith, you are invited to the Teahouse!
[edit]Hi Bradley Goldsmith! Thanks for contributing to Wikipedia. We hope to see you there!
Delivered by HostBot on behalf of the Teahouse hosts 16:10, 19 January 2020 (UTC) |
Welcome!
[edit]Hello, Bradley Goldsmith, and welcome to Wikipedia! My name is Elysia and I work with the Wiki Education Foundation; I help support students who are editing as part of a class assignment.
I hope you enjoy editing here. If you haven't already done so, please check out the student training library, which introduces you to editing and Wikipedia's core principles. You may also want to check out the Teahouse, a community of Wikipedia editors dedicated to helping new users. Below are some resources to help you get started editing.
Handouts
|
---|
Additional Resources
|
|
If you have any questions, please don't hesitate to contact me on my talk page. Elysia (Wiki Ed) (talk) 21:42, 24 January 2020 (UTC)
wiki edit midterm
[edit]I re-wrote the lead section for History of Maxwell's Equations Feb. 12, 2020:
In electromagnetism, one of the fundamental fields of physics, the introduction of Maxwell's equations (mainly in "A Dynamical Theory of the Electromagnetic Field") was one of the most important aggregations of empirical facts in the history of physics. Beginning in the 1850s, James Clerk Maxwell began studying the work of Michael Faraday, whose experiments on magnetism and electricity led him to a qualitative model of electromagnetism. Maxwell translated Faraday's notion of "lines of force" into mathematical formulas in an 1855 paper,[1] presenting the earliest form of the equations by modifying Ampère's circuital law with the introduction of a displacement current term. His equations established a novel mathematized relationship between light and electromagnetism, implying that light propagates as electromagnetic waves. Increasingly powerful mathematical descriptions of the electromagnetic field were developed, continuing into the twentieth century, enabling the equations to take on simpler forms by advancing more sophisticated mathematics. Notably, Oliver Heaviside employed his vector calculus to synthesize Maxwell's over 20 equations into the four recognizable ones which modern physicists use. Maxwell's equations also inspired Albert Einstein in developing the theory of special relativity.