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Main Author: Toussaint, Vladimir
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.17959
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author Toussaint, Vladimir
author_facet Toussaint, Vladimir
contents Detecting the Unruh effect is a major challenge in fundamental physics. It is known that exciting massive fields with the Unruh thermal bath is heavily suppressed when the field's rest energy is much larger than the acceleration energy scale, $Mc^2 \gg\hbar a/c$. However, the standard literature lacks an explicit quantitative derivation of this suppression. In this work, we first fill this gap by deriving the exponential suppression, $\sim \exp(-\text{constant}\times Mc^2/(\hbar a/c))$, in two different frameworks: a (3+1)-dimensional Unruh-DeWitt detector and a (1+1)-dimensional cavity QED setup. This shows the suppression is universal and sets an insurmountable barrier for any detection method that relies on exciting massive fields. For an electron-mass field at achievable accelerations ($a \sim 10^{20}$ m/s$^2$), the suppression exceeds $10^9$ orders of magnitude. To avoid this suppression, the field's rest energy must be less than or of the order of the acceleration energy scale, $M c^2 \lesssim \hbar a / c$. Achieving this condition, however, requires astronomically high accelerations. For example, detecting the effect for an electron-mass field would require accelerations of $a \gtrsim 4.6\times 10^{29}$ m/s$^2$, which is far beyond experimental reach. While using a massless field avoids this suppression, we show the best strategy is not to avoid mass, but to engineer a small effective mass that satisfies the optimal condition $\hbar a / c \gg M_{\text{eff}} c^2$. We propose a concrete implementation using a superconducting circuit with a Josephson persistent-current qubit (the analog of a UDW detector) coupled to a microwave resonator (the analog of the scalar field). For this system, the optimal condition is $2I_pΔΦ\gg Δ$, where $I_p$ is the persistent current, $ΔΦ$ is the magnetic flux swing, and $Δ$ is the qubit's tunneling energy gap....
format Preprint
id arxiv_https___arxiv_org_abs_2512_17959
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Detecting the Unruh Effect via an Engineered Low-Mass Field in a Superconducting Qubit
Toussaint, Vladimir
General Relativity and Quantum Cosmology
Detecting the Unruh effect is a major challenge in fundamental physics. It is known that exciting massive fields with the Unruh thermal bath is heavily suppressed when the field's rest energy is much larger than the acceleration energy scale, $Mc^2 \gg\hbar a/c$. However, the standard literature lacks an explicit quantitative derivation of this suppression. In this work, we first fill this gap by deriving the exponential suppression, $\sim \exp(-\text{constant}\times Mc^2/(\hbar a/c))$, in two different frameworks: a (3+1)-dimensional Unruh-DeWitt detector and a (1+1)-dimensional cavity QED setup. This shows the suppression is universal and sets an insurmountable barrier for any detection method that relies on exciting massive fields. For an electron-mass field at achievable accelerations ($a \sim 10^{20}$ m/s$^2$), the suppression exceeds $10^9$ orders of magnitude. To avoid this suppression, the field's rest energy must be less than or of the order of the acceleration energy scale, $M c^2 \lesssim \hbar a / c$. Achieving this condition, however, requires astronomically high accelerations. For example, detecting the effect for an electron-mass field would require accelerations of $a \gtrsim 4.6\times 10^{29}$ m/s$^2$, which is far beyond experimental reach. While using a massless field avoids this suppression, we show the best strategy is not to avoid mass, but to engineer a small effective mass that satisfies the optimal condition $\hbar a / c \gg M_{\text{eff}} c^2$. We propose a concrete implementation using a superconducting circuit with a Josephson persistent-current qubit (the analog of a UDW detector) coupled to a microwave resonator (the analog of the scalar field). For this system, the optimal condition is $2I_pΔΦ\gg Δ$, where $I_p$ is the persistent current, $ΔΦ$ is the magnetic flux swing, and $Δ$ is the qubit's tunneling energy gap....
title Detecting the Unruh Effect via an Engineered Low-Mass Field in a Superconducting Qubit
topic General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2512.17959