Noncommutative geometry of Zitterbewegung

Michał Eckstein; Nicolas Franco; Tomasz Miller

doi:10.1103/PhysRevD.95.061701

Noncommutative geometry of Zitterbewegung

Michał Eckstein, Nicolas Franco, Tomasz Miller

Namur Institute for Complex Systems

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Abstract

Drawing from the advanced mathematics of noncommutative geometry, we model a "classical" Dirac fermion propagating in a curved spacetime. We demonstrate that the inherent causal structure of the model encodes the possibility of Zitterbewegung - the "trembling motion" of the fermion. We recover the well-known frequency of Zitterbewegung as the highest possible speed of change in the fermion's "internal space." Furthermore, we show that the bound does not change in the presence of an external electromagnetic field and derive its explicit analogue when the mass parameter is promoted to a Yukawa field. We explain the universal character of the model and discuss a table-top experiment in the domain of quantum simulation to test its predictions.

Original language	English
Article number	061701
Journal	Physical Review D
Volume	95
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevD.95.061701
Publication status	Published - 23 Mar 2017

Keywords

noncommutative geometry
Zitterbewegung

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10.1103/PhysRevD.95.061701

PhysRevD.95.061701Final published version, 150 KB

https://arxiv.org/abs/1610.10083

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title = "Noncommutative geometry of Zitterbewegung",

abstract = "Drawing from the advanced mathematics of noncommutative geometry, we model a {"}classical{"} Dirac fermion propagating in a curved spacetime. We demonstrate that the inherent causal structure of the model encodes the possibility of Zitterbewegung - the {"}trembling motion{"} of the fermion. We recover the well-known frequency of Zitterbewegung as the highest possible speed of change in the fermion's {"}internal space.{"} Furthermore, we show that the bound does not change in the presence of an external electromagnetic field and derive its explicit analogue when the mass parameter is promoted to a Yukawa field. We explain the universal character of the model and discuss a table-top experiment in the domain of quantum simulation to test its predictions.",

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N2 - Drawing from the advanced mathematics of noncommutative geometry, we model a "classical" Dirac fermion propagating in a curved spacetime. We demonstrate that the inherent causal structure of the model encodes the possibility of Zitterbewegung - the "trembling motion" of the fermion. We recover the well-known frequency of Zitterbewegung as the highest possible speed of change in the fermion's "internal space." Furthermore, we show that the bound does not change in the presence of an external electromagnetic field and derive its explicit analogue when the mass parameter is promoted to a Yukawa field. We explain the universal character of the model and discuss a table-top experiment in the domain of quantum simulation to test its predictions.

AB - Drawing from the advanced mathematics of noncommutative geometry, we model a "classical" Dirac fermion propagating in a curved spacetime. We demonstrate that the inherent causal structure of the model encodes the possibility of Zitterbewegung - the "trembling motion" of the fermion. We recover the well-known frequency of Zitterbewegung as the highest possible speed of change in the fermion's "internal space." Furthermore, we show that the bound does not change in the presence of an external electromagnetic field and derive its explicit analogue when the mass parameter is promoted to a Yukawa field. We explain the universal character of the model and discuss a table-top experiment in the domain of quantum simulation to test its predictions.

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Noncommutative geometry of Zitterbewegung

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