Radiation from charged particles due to explicit symmetry breaking in a gravitational field

Tamburini, Fabrizio; Licata, Ignazio

doi:10.1142/s0219887818501220

Cited by 7 publications

(10 citation statements)

References 28 publications

(32 reference statements)

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“…Finally the spectral domain intensity output with arbitrary phase θ, can be written as follows. [1][2][3]23]…”

Section: Mathematical Analysis Of Gravitational Equivalence Of Sagnac...mentioning

confidence: 99%

Spectral switch anomalies in a Sagnac interferometer with respect to a Galilean frame

Sadhukhan

Brundavanam³

et al. 2022

J. Opt. Soc. Am. A

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“…Finally the spectral domain intensity output with arbitrary phase θ, can be written as follows. [1][2][3]23]…”

Section: Mathematical Analysis Of Gravitational Equivalence Of Sagnac...mentioning

confidence: 99%

Spectral switch anomalies in a Sagnac interferometer with respect to a Galilean frame

Sadhukhan

Brundavanam³

et al. 2022

J. Opt. Soc. Am. A

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“…The Rindler spacetime is a hyperbolically accelerated reference frame that is comparable to a homoge-neous gravitational field, a solution of Einstein's equations in General Relativity, used to study several fundamental physical problems like the description of a free falling radiating charge [31,32]. This manifold acts as a Minkowski spacetime with coordinates adapted to a boost-Killing vector field and is equivalent to a uniformly accelerated observer where all Lorentz boosts, rotations and their combinations are continuously connected to the identity operator.…”

Section: A H = Xp and The Majorana Towermentioning

confidence: 99%

Majorana quanta, string scattering, curved spacetimes and the Riemann Hypothesis

Tamburini,

Licata

2021

Preprint

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The Riemann Hypothesis states that the Riemann zeta function ζ(z) admits a set of "non-trivial" zeros that are complex numbers supposed to have real part 1/2. Their distribution on the complex plane is thought to be the key to determine the number of prime numbers before a given number. We analyze two approaches. In the first approach, suggested by Hilbert and Pólya, one has to find a suitable Hermitian or unitary operator whose eigenvalues distribute like the zeros of ζ(z).In the other approach one instead compares the distribution of the zeta zeros and the poles of the scattering matrix S of a system. We apply the infinite-components Majorana equation in a Rindler spacetime to both methods and then focus on the S-matrix approach describing the bosonic open string for tachyonic states. In this way we can explain the still unclear point for which the poles and zeros of the S-matrix overlaps the zeros of ζ(z) and exist always in pairs and related via complex conjugation. This occurs because of the relationship between the angular momentum and energy/mass eigenvalues of Majorana states and from the analysis of the dynamics of the poles of S. As shown in the literature, if this occurs, then the Riemann Hypothesis can in principle be satisfied.

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“…LEQGs are related through the principle of equivalence (PE). The PE states the equivalence between the gravitational and inertial mass, or, in other words, an acceleration is locally equivalent to the effect of a gravitational field and is one of the milestones of General Relativity and related to the paradox of a free falling radiating charged particle in a gravitational field [76]. In the weak gravity limit one can state that the motion of a point-like test particle in a uniform gravitational field with acceleration g is indistinguishable from that in with acceleration −g in a region where gravity is null.…”

Section: Gravitational Field Fluctuations and The Equivalence Principlementioning

confidence: 99%

Testing the equivalence principle and discreteness of spacetime through the t3 gravitational phase with quantum information technology

Tamburini

Licata

2020

Physics Letters B

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We propose a new thought experiment, based on present-day Quantum Information Technologies, to measure quantum gravitational effects through the Bose-Marletto-Vedral (BMV) effect [1][2][3][4] by revealing the gravitational t 3 phase term, its expected relationships with low-energy quantum gravity phenomena and test the equivalence principle of general relativity. The technique here proposed promise to reveal gravitational field fluctuations from the analysis of the stochastic noise associated to an ideal output of a measurement process of a quantum system. To improve the sensitivity we propose to cumulate the effects of the gravitational field fluctuations in time on the outputs of a series of independent measurements acted on entangled states of particles, like in the building of a quantum cryptographic key, and extract from the associated time series the effect of the expected gravitational field fluctuations. In fact, an ideal quantum cryptographic key, built with the sharing of maximally entangled states of particles, is represented by a random sequence of uncorrelated symbols mathematically described by a perfect white noise, a stochastic process with zero mean and without correlation between its values taken at different times. Gravitational field perturbations, including quantum gravity fluctuations and gravitational waves, introduce additional phase terms that decohere the entangled pairs used to build the quantum cryptographic key, with the result of coloring the white noise [5,6]. We find that this setup, built with massive mesoscopic particles, can potentially reveal the t 3 gravitational phase term and thus, the BMV effect.

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Radiation from charged particles due to explicit symmetry breaking in a gravitational field

Cited by 7 publications

References 28 publications

Spectral switch anomalies in a Sagnac interferometer with respect to a Galilean frame

Spectral switch anomalies in a Sagnac interferometer with respect to a Galilean frame

Majorana quanta, string scattering, curved spacetimes and the Riemann Hypothesis

Testing the equivalence principle and discreteness of spacetime through the t3 gravitational phase with quantum information technology

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