# [SCI] Electromagnetic Wave Theory

**Electromagnetic Wave Theory** is the understanding that oscillating electric and magnetic fields propagate as transverse waves at the speed of light c = 1/√(ε₀μ₀) ≈ 3×10⁸ m/s, unifying optics and electromagnetism.

## Overview

Maxwell's equations predict wave solutions in free space, with velocity exactly equal to the measured speed of light — leading Maxwell to conclude that light itself is an electromagnetic wave (1865). Hertz (1887) generated and detected radio waves in the laboratory, confirming the prediction. The Michelson–Morley experiment (1887) failed to detect the expected ether drift, revealing that the speed of light is constant in all frames — the key experimental input to special relativity.

Oliver Heaviside reformulated Maxwell's equations into their modern compact form (1884). The discovery spawned radio, radar, microwave engineering, and eventually all of wireless technology.

## Key Figures & Recognition

- **James Clerk Maxwell** (1831–1879): Predicted EM waves, 1865.
- **Heinrich Hertz** (1857–1894): First experimental demonstration of radio waves, 1887.
- **Albert Michelson** (1852–1931): Nobel Prize 1907 (for optical precision instruments and Michelson–Morley).

## Seminal Papers

- Maxwell, J.C. "A Dynamical Theory of the Electromagnetic Field." *Phil. Trans.* 155 (1865).
- Hertz, H. "Über Strahlen elektrischer Kraft." *Ann. Phys.* 272 (1888).

## What This Enables
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- **[SCI] Special Relativity** — The Michelson–Morley experiment (constant c) and Lorentz covariance of Maxwell's equations motivated SR directly.
- **[TECH] Radio & Wireless Communication** — Oscillating antennas radiate EM waves that carry encoded information across space without wires.
- **[TECH] Vacuum Tube Electronics** — Thermionic emission and electron–field interactions, both EM phenomena, are the basis of valve operation.
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# Parents

* [SCI] Classical Electromagnetism
* [SCI] Classical Electromagnetism