Covariant formulation of Aharonov-Bohm electrodynamics and its application to coherent tunnelling

arXiv: General Physics Pub Date : 2017-02-01 DOI:10.1142/9789813232044_0023

G. Modanese

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引用次数: 5

Abstract

The extended electrodynamic theory introduced by Aharonov and Bohm (after an earlier attempt by Ohmura) and recently developed by Van Vlaenderen and Waser, Hively and Giakos, can be re-written and solved in a simple and effective way in the standard covariant 4D formalism. This displays more clearly some of its features. The theory allows a very interesting consistent generalization of the Maxwell equations. In particular, the generalized field equations are compatible with sources (classical, or more likely of quantum nature) for which the continuity/conservation equation $\partial_\mu j^\mu=0$ is not valid everywhere, or is valid only as an average above a certain scale. And yet, remarkably, in the end the observable $F^{\mu \nu}$ field is still generated by a conserved effective source which we denote as $(j^\nu+i^\nu)$, being $i^\nu$ a suitable non-local function of $j^\nu$. This implies that any microscopic violation of the charge continuity condition is "censored" at the macroscopic level, although it has real consequences, because it generates a non-Maxwellian component of the field. We consider possible applications of this formalism to condensed-matter systems with macroscopic quantum tunneling. The extended electrodynamics can also be coupled to fractional quantum systems.

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Aharonov-Bohm电动力学协变公式及其在相干隧穿中的应用

由Aharonov和Bohm介绍的扩展电动力学理论(在Ohmura的早期尝试之后)，最近由Van Vlaenderen和Waser, Hively和Giakos发展，可以在标准协变4D形式主义中以简单有效的方式重写和求解。这更清楚地显示了它的一些特性。这个理论允许对麦克斯韦方程组进行非常有趣的一致推广。特别是，广义场方程与源(经典的，或者更可能是量子性质的)兼容，其中连续性/守恒方程$\partial_\mu j^\mu=0$不是处处有效，或者仅作为一定尺度以上的平均值有效。然而，值得注意的是，最终可观察到的$F^{\mu \nu}$场仍然是由一个保守的有效源产生的，我们表示为$(j^\nu+i^\nu)$, $i^\nu$是$j^\nu$的一个合适的非局部函数。这意味着任何微观上对电荷连续性条件的违反都在宏观层面上被“截除”，尽管它有实际的后果，因为它产生了场的非麦克斯韦分量。我们考虑了这种形式在具有宏观量子隧穿的凝聚态系统中的可能应用。扩展的电动力学也可以耦合到分数量子系统。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv: General Physics

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