Waiting for Unruh

Abstract

How long does a uniformly accelerated observer need to interact with a quantum field in order to record thermality in the Unruh temperature? We address this question for a pointlike Unruh-DeWitt detector, coupled linearly to a real Klein-Gordon field of mass m0 and treated within first order perturbation theory, in the limit of large detector energy gap Egap. We first show that when the interaction duration T is fixed, thermality in the sense of detailed balance cannot hold as Egap∞, and this property generalises from the Unruh effect to any Kubo-Martin-Schwinger state satisfying certain technical conditions. We then specialise to a massless field in four spacetime dimensions and show that detailed balance does hold when T grows as a power-law in Egap as Egap∞, provided the switch-on and switch-off intervals are stretched proportionally to T and the switching function has sufficiently strong Fourier decay. By contrast, if T grows by stretching a plateau in which the interaction remains at constant strength but keeping the duration of the switch-on and switch-off intervals fixed, detailed balance at Egap∞ requires T to grow faster than any polynomial in Egap, under mild technical conditions. These results also hold for a static detector in a Minkowski heat bath. The results limit the utility of the large Egap regime as a probe of thermality in time-dependent versions of the Hawking and Unruh effects, such as an observer falling into a radiating black hole. They may also have implications on the design of prospective experimental tests of the Unruh effect.