Zilch (electromagnetica)

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In Physice, zilch quantitas conservata retis electromagneticae est.

Daniel M. Lipkin observabat quod si quantitates ita definiat

{\begin{aligned}Z^{0}&=\mathbf {E} \cdot \nabla \times \mathbf {E} +\mathbf {B} \cdot \nabla \times \mathbf {B} \\[4pt]\mathbf {Z} &={\frac {1}{c}}\left(\mathbf {E} \times {\frac {d}{dt}}\mathbf {E} +\mathbf {B} \times {\frac {d}{dt}}\mathbf {B} \right)\end{aligned}}

tunc illae Maxwellis aequationes

\partial _{0}Z^{0}+\nabla \cdot \mathbf {Z} =0

quae eam totam "zilchem" $\int Z^{0}\,d^{3}x$ constantem esse implicant ( $\mathbf {Z}$ "zilch currens" est). Temperante resultum, Lipkin leges novem conservationis invenit, tota non relata ad strictum-energiam tensorem. Is "zilch" huic quantitati appellavit propter defectionem apparentem significationis physicalis.^[1]^[2]

Zilch quoque per dualem tensorem electromagneticem exprimatur: ${\hat {F}}^{\mu \nu }=(1/2)\epsilon ^{\mu \nu \rho \sigma }F_{\rho \sigma }$ as $Z_{\nu }^{\mu }\rho ={\hat {F}}^{\mu \lambda }F_{\lambda \nu ,\rho }-F^{\mu \lambda }{\hat {F}}_{\lambda \nu ,\rho }$ .

Post-ea demonstratur quod Zilch pars est numuri infiniti earum zilchis-simile quantitatum conservatarum, propertas generalis liberorum camporum.^[3] Zilch onus Noether quid associatum cum invariantia aequationum Maxwellis sub rotationibus dualitatis est.^[4]

Dum Zilch ample obscurum manet, occasionaliter detegebatur. Appellaretur "Chiralitas Opticalis", ut hunc degradum Asymmetriae Chiralis per Rationem Excitationis ejus chiralis moleculi parvuli ab incidente campo electromagnetico determinat.^[5]

References recensere

↑ Lipkin, D.M. (1964). "Existence of a New Conservation Law in Electromagnetic Theory". Journal of Mathematical Physics 5 (696): 696-700
↑ Wheeler, N.A. Classical electrodynamics course notes. Reed College. 1980/81. p. 241-245
↑ Kibble, T.W.B. (1965). "Conservation Laws for Free Fields". Journal of Mathematical Physics 6 (7): 1022-1026
↑ Cameron, R.P.; Barnett, S.M. (2012). "Electric–magnetic symmetry and Noether's theorem". New Journal of Physics 14 (12): 123019
↑ Tang, Y.; Cohen, A.E. (2010). "Optical Chirality and Its Interaction with Matter". Physical Review Letters 104: 163901-1-4

[1] Lipkin, D.M. (1964). "Existence of a New Conservation Law in Electromagnetic Theory". Journal of Mathematical Physics 5 (696): 696-700

[2] Wheeler, N.A. Classical electrodynamics course notes. Reed College. 1980/81. p. 241-245

[kibble-3] Kibble, T.W.B. (1965). "Conservation Laws for Free Fields". Journal of Mathematical Physics 6 (7): 1022-1026

[4] Cameron, R.P.; Barnett, S.M. (2012). "Electric–magnetic symmetry and Noether's theorem". New Journal of Physics 14 (12): 123019

[5] Tang, Y.; Cohen, A.E. (2010). "Optical Chirality and Its Interaction with Matter". Physical Review Letters 104: 163901-1-4

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