Abstract
The Unruh effect states that a uniformly linearly accelerated observer with proper acceleration $a$ experiences Minkowski vacuum as a thermal state in the temperature $T_{\text{lin}} = a/(2\pi)$, operationally measurable via the detailed balance condition between excitation and de-excitation probabilities. An observer in uniform circular motion experiences a similar Unruh-type temperature $T_{\text{circ}}$, operationally measurable via the detailed balance condition, but $T_{\text{circ}}$ depends not just on the proper acceleration but also on the orbital radius and on the excitation energy. We establish analytic results for $T_{\text{circ}}$ for a massless scalar field in $3+1$ and $2+1$ spacetime dimensions in several asymptotic regions of the parameter space, and we give numerical results in the interpolating regions. In the ultrarelativistic limit, we verify that in $3+1$ dimensions $T_{\text{circ}}$ is of the order of $T_{\text{lin}}$ uniformly in the energy, as previously found by Unruh, but in $2+1$ dimensions $T_{\text{circ}}$ is significantly lower at low energies. We translate these results to an analogue spacetime nonrelativistic field theory in which the circular acceleration effects may become experimentally testable in the near future. We establish in particular that the circular motion analogue Unruh temperature grows arbitrarily large in the near-sonic limit, encouragingly for the experimental prospects, but the growth is weaker in effective spacetime dimension $2+1$ than in $3+1$.
Highlights
The Unruh effect [1, 2, 3] states that a linearly uniformly accelerated observer in Minkowski spacetime reacts to a quantum field in its Minkowski vacuum by excitations and de-excitations with the characteristics of a thermal state in the Unruh temperature a /(2πckB), where a is the observer’s proper acceleration
Beyond the ultrarelativistic limit the discrepancy is larger, as we show by analytic results in several limits and by numerical results in the interpolating regions
This is in particular the case for uniform linear acceleration in Minkowski vacuum, where T is independent of E and equal to a/(2π), with a being the magnitude of the proper acceleration [3]: this is the usual Unruh effect
Summary
The Unruh effect [1, 2, 3] states that a linearly uniformly accelerated observer in Minkowski spacetime reacts to a quantum field in its Minkowski vacuum by excitations and de-excitations with the characteristics of a thermal state in the Unruh temperature a /(2πckB), where a is the observer’s proper acceleration (for textbooks and reviews, see [4, 5, 6, 7]). For the (3 + 1)-dimensional relativistic system, we confirm that the circular motion Unruh temperature Tcirc agrees with the linear motion Unruh temperature within an energy-dependent factor of order unity in the ultrarelativistic limit, in agreement with the previous analytic scalar field results by Takagi [35], Muller [52] and Unruh [42] (the published version [43] of [42] focused on the electromagnetic field), and consistently with the numerics given in [33, 42, 64]. In asymptotic formulas, O(x) denotes a quantity such that O(x)/x is bounded as x → 0, o(x) denotes a quantity such that o(x)/x → 0 as x → 0, O(1) denotes a quantity that remains bounded in the limit under consideration, and o(1) denotes a quantity that goes to zero in the limit under consideration
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