Relevant bibliographies by topics / Non-inertial frames

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Academic literature on the topic 'Non-inertial frames'

Author: Grafiati
Published: 4 June 2021
Last updated: 12 June 2025

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Journal articles on the topic "Non-inertial frames"

1

Papini, Giorgio. "Spin currents in non-inertial frames." Physics Letters A 377, no. 13 (2013): 960–63. http://dx.doi.org/10.1016/j.physleta.2013.02.032.

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2

Metwally, Nasser, and Alaa Sagheer. "Quantum coding in non-inertial frames." Quantum Information Processing 13, no. 3 (2013): 771–80. http://dx.doi.org/10.1007/s11128-013-0688-4.

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3

Moreno, M., and J. A. del Río. "Quantum mechanics for non-inertial reference frames." European Journal of Physics 42, no. 4 (2021): 045405. http://dx.doi.org/10.1088/1361-6404/abfd3d.

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4

Lee, Jeffrey S., and Gerald B. Cleaver. "The relativistic blackbody spectrum in inertial and non-inertial reference frames." New Astronomy 52 (April 2017): 20–28. http://dx.doi.org/10.1016/j.newast.2016.10.003.

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5

Wang, Long-Fei, Ming-Ming Du, and Liu Ye. "Protecting quantum coherence in an open system under non-inertial frames." Modern Physics Letters B 31, no. 35 (2017): 1750336. http://dx.doi.org/10.1142/s0217984917503365.

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In this paper, we explore the dynamics and protection of quantum coherence in an open system under non-inertial frames by weak measurement and reversal, and design four strategies to protect the quantum coherence of an initial two-qubit entangled state, when the systems suffer from amplitude damping (AD) channel and one subsystem is under non-inertial frames. In practice, there is no strict inertial frames, decoherence and degradation of the quantum coherence caused by the Unruh effect form acceleration will have a significant interaction, therefore it is important to find some means to protect quantum coherence under non-inertial frames.
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6

Miao-Fu, He, and Huang Cheng. "Realization of the Local Inertial Geocentric Frame in Relativity." Symposium - International Astronomical Union 141 (1990): 430. http://dx.doi.org/10.1017/s0074180900087210.

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There are two kinds of geocentric frames: local inertial and non-inertial geocentric frames. Ashby et al successfully constructed a local inertial geocentric frame in the neighborhood of the gravitating Earth. In the frame with origin at the Earth's center, the gravitational effects of the sun and of planets other than the Earth are basically reduced to their tidal forces, with very small relativistic corrections.However, the spatial base vectors of the local inertial frame essentially experience the geodesic (or deSitter) precession with respect to the solar system barycentric frame. Hence the realization of the local inertial frame requires that the general precession should exclude the geodesic precession. This requirement is inconsistent with the convention that the amount of geodesic precession is included in that of the general precession given by Lieske et al.
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7

Crater, Horace W., and Luca Lusanna. "Non-inertial frames in Minkowski space-time, accelerated either mathematical or dynamical observers and comments on non-inertial relativistic quantum mechanics." International Journal of Geometric Methods in Modern Physics 11, no. 10 (2014): 1450086. http://dx.doi.org/10.1142/s0219887814500868.

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After a review of the existing theory of non-inertial frames and mathematical observers in Minkowski space-time we give the explicit expression of a family of such frames obtained from the inertial ones by means of point-dependent Lorentz transformations as suggested by the locality principle. These non-inertial frames have non-Euclidean 3-spaces and contain the differentially rotating ones in Euclidean 3-spaces as a subcase. Then we discuss how to replace mathematical accelerated observers with dynamical ones (their world-lines belong to interacting particles in an isolated system) and how to define Unruh–DeWitt detectors without using mathematical Rindler uniformly accelerated observers. Also some comments are done on the transition from relativistic classical mechanics to relativistic quantum mechanics in non-inertial frames.
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8

Doukas, Jason, Gerardo Adesso, Stefano Pirandola, and Andrzej Dragan. "Discriminating quantum field theories in non-inertial frames." Classical and Quantum Gravity 32, no. 3 (2015): 035013. http://dx.doi.org/10.1088/0264-9381/32/3/035013.

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9

Liu, Gordon. "An Alternative Theory on the Spacetime of Non-inertial Reference Frame." Applied Physics Research 9, no. 5 (2017): 90. http://dx.doi.org/10.5539/apr.v9n5p90.

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In present paper, we have proposed an alternative theory on the spacetime of non-inertial reference frame (NRF) which bases on the requirement of general completeness (RGC) and the principle of equality of all reference frames (PERF). The RGC is that the physical equations used to describe the dynamics of matter and/or fields should include the descriptions that not only the matter and/or fields are at rest, but also they move relative to this reference frame, and the structure of the spacetime of reference frame has been considered. The PERF is that any reference frame can be used to describe the motion of matter and/or fields. The spacetime of NRF is inhomogeneous and deformed caused by the accelerating motion of the reference frame. The inertial force is the manifestation of deformed spacetime. The Riemann curvature tensor of the spacetime of NRF equals zero, but the Riemann-Christoffel symbol never vanishs no matter what coordinate system is selected in the NRF. The physical equations satisfied the RGC remain covariance under the coordinate transformation between the reference frames. Mach’s principle is incorrect. The problem of spacetime of NRF can be solved without considering gravitation.
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10

Lee, Jeffrey S., and Gerald B. Cleaver. "Relativistic drag and emission radiation pressures in an isotropic photonic gas." Modern Physics Letters A 31, no. 19 (2016): 1650118. http://dx.doi.org/10.1142/s0217732316501182.

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By invoking the relativistic spectral radiance, as derived by Lee and Cleaver,1 the drag radiation pressure of a relativistic planar surface moving through an isotropic radiation field, with which it is in thermal equilibrium, is determined in inertial and non-inertial frames. The forward- and backward-directed emission radiation pressures are also derived and compared. A fleeting (inertial frames) or ongoing (some non-inertial frames) Carnot cycle is shown to exist as a result of an intra-surfaces temperature gradient. The drag radiation pressure on an object with an arbitrary frontal geometry is also described.
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