| 1. | :: The OP is referrring to the classical electron radius.
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| 2. | 2.8179 ?10 & minus; 15 m is the classical electron radius.
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| 3. | Where a _ 0 is the Bohr radius and r _ 0 is the classical electron radius.
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| 4. | Paul Drude in 1900 proposed the first theoretical model for a classical electron moving through a metallic solid.
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| 5. | This technique also uses an antibody to the protein of interest, along with classical electron microscopy techniques.
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| 6. | Where is the atomic number, the length of the wave vector, and the classical electron radius.
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| 7. | It replaces Einstein's " A " coefficient and explains that the classical electron is stable on Rydberg's classical orbits.
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| 8. | :: : : : Classical electron radius is a useful characteristic length for the extent of the electric field around an electron.
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| 9. | Furthermore, it is known that the Einstein� Maxwell� Dirac system admits of solitonic solutions, i . e ., classical electrons and photons.
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| 10. | The Electron article also tells you the mass and has some discussion of the size ( in terms of the " classical electron radius " ).
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