# [SCI] Theory of Metals
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**Theory of Metals** is the quantum mechanical description of electrons in crystalline solids, explaining electrical and thermal conductivity, the distinction between metals and insulators, and the foundations of solid-state electronics.
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## Overview
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Paul Drude's classical model (1900) treated electrons as a free gas, giving the correct order of magnitude for conductivity. Arnold Sommerfeld (1927) applied Fermi–Dirac statistics to electron gas, resolving many failures of the Drude model. Felix Bloch (1928) derived that electrons in a periodic crystal lattice form bands — energy ranges of allowed and forbidden states. Alan Wilson (1931) explained the metal/insulator/semiconductor distinction in terms of band filling.
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Band theory is the bedrock of semiconductor physics: a semiconductor has a filled valence band and an empty conduction band separated by a small gap that can be bridged by thermal excitation or doping.
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## Key Figures & Recognition
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- **Arnold Sommerfeld** (1868–1951): Quantum electron gas; supervised more future Nobel laureates than anyone.
- **Felix Bloch** (1905–1983): Band theory of solids. **Nobel Prize 1952** (for NMR).
- **Alan Wilson** (1906–1995): Band theory of semiconductors, 1931.
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## Seminal Papers
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- Drude, P. "Zur Elektronentheorie der Metalle." *Ann. Phys.* 1 (1900).
- Bloch, F. "Über die Quantenmechanik der Elektronen in Kristallgittern." *Z. Phys.* 52 (1928).
- Wilson, A.H. "The Theory of Electronic Semi-Conductors." *Proc. R. Soc. A* 133 (1931).
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# Parents
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* [SCI] Quantum Mechanics⏎