Dennis Raetzel scite author profile

To serve as a dispersion relation, a cotangent bundle function must satisfy three simple algebraic properties. These conditions are derived from the inescapable physical requirements to have predictive matter field dynamics and an observer-independent notion of positive energy. Possible modifications of the standard relativistic dispersion relation are thereby severely restricted. For instance, the dispersion relations associated with popular deformations of Maxwell theory by Gambini-Pullin or Myers-Pospelov are not admissible

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The Unruh Effect in General Boundary Quantum Field Theory

Colosi

Raetzel²

2013

SIGMA

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Abstract. In the framework of the general boundary formulation (GBF) of scalar quantum field theory we obtain a coincidence of expectation values of local observables in the Minkowski vacuum and in a particular state in Rindler space. This coincidence could be seen as a consequence of the identification of the Minkowski vacuum as a thermal state in Rindler space usually associated with the Unruh effect. However, we underline the difficulty in making this identification in the GBF. Beside the Feynman quantization prescription for observables that we use to derive the coincidence of expectation values, we investigate an alternative quantization prescription called Berezin-Toeplitz quantization prescription, and we find that the coincidence of expectation values does not exist for the latter.

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Optical solitons in curved spacetime

Spengler

Belenchia

Raetzel

et al. 2023

Class. Quantum Grav.

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Light propagation in curved spacetime is at the basis of some of the most stringent tests of Einstein’s general relativity. At the same time, light propagation in media is at the basis of several communication systems. Given the ubiquity of the gravitational ﬁeld, and the exquisite level of sensitivity of optical measurements, the time is ripe for investigations combining these two aspects and studying light propagation in media located in curved spacetime. In this work, we focus on the eﬀect of a weak gravitational ﬁeld on the propagation of optical solitons in non-linear optical media. We derive a non-linear Schr ¨odinger equation describing the propagation of an optical pulse in an eﬀective, gradient-index medium in ﬂat spacetime, encoding both the material properties and curved spacetime eﬀects. In analyzing the special case of propagation in a 1D optical ﬁber, we also include the eﬀect of mechanical deformations and show it to be the dominant eﬀect for a ﬁber oriented in the radial direction in Schwarzschild spacetime.

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Dennis Raetzel

Geometry of physical dispersion relations

The Unruh Effect in General Boundary Quantum Field Theory

Optical solitons in curved spacetime

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