Using “Particle Density” of “Graviton Gas”, to Obtain Value of Cosmological Constant

Using “Particle Density” of “Graviton Gas”, to Obtain Value of Cosmological Constant

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摘要 We use the work of de Vega, Sanchez, and Comes (1997), to approximate the “particle density” of a “graviton gas”. This “particle density” derivation is compared with Dolgov’s (1997) expression of the Vacuum energy in terms of a phase transition. The idea is to have a quartic potential, and then to utilize the Bogomol’nyi inequality to refine what the phase transition states. We utilize Ng, Infinite quantum information procedures to link our work with initial entropy and other issues and close with a variation in the HUP: at the start of the expansion of the universe. We use the work of de Vega, Sanchez, and Comes (1997), to approximate the “particle density” of a “graviton gas”. This “particle density” derivation is compared with Dolgov’s (1997) expression of the Vacuum energy in terms of a phase transition. The idea is to have a quartic potential, and then to utilize the Bogomol’nyi inequality to refine what the phase transition states. We utilize Ng, Infinite quantum information procedures to link our work with initial entropy and other issues and close with a variation in the HUP: at the start of the expansion of the universe.

作者 Andrew Beckwith Andrew Beckwith(Department of Physics, College of Physics, Chongqing University, Chongqing, China)

机构地区 Department of Physics

出处《Journal of High Energy Physics, Gravitation and Cosmology》 CAS 2023年第1期168-173,共6页 高能物理（英文）

关键词 Graviton Gas Partition Function Modified HUP Symmetry Breaking Potential Graviton Gas Partition Function Modified HUP Symmetry Breaking Potential

分类号 O17 [理学—数学]

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1Andrew Walcott Beckwith.Gedanken Experiment for Refining the Unruh Metric Tensor Uncertainty Principle via Schwarzschild Geometry and Planckian Space-Time with Initial Nonzero Entropy and Applying the Riemannian-Penrose Inequality and Initial Kinetic Energy for a Lower Bound to Graviton Mass (Massive Gravity)[J].Journal of High Energy Physics, Gravitation and Cosmology,2016,2(1):106-124. 被引量：36
2Andrew Walcott Beckwith.Non Linear Electrodynamics Contributing to a Minimum Vacuum Energy (“Cosmological Constant”) Allowed in Early Universe Cosmology[J].Journal of High Energy Physics, Gravitation and Cosmology,2016,2(1):25-32. 被引量：3
3Andrew Walcott Beckwith.Gedanken Experiment for Fluctuation of Mass of a Graviton, Based on the Trace of GR Stress Energy Tensor-Pre Planckian Conditions that Lead to Gaining of Graviton Mass, and Planckian Conditions That Lead to Graviton Mass Shrinking to 10-62 Grams[J].Journal of High Energy Physics, Gravitation and Cosmology,2016,2(1):19-24. 被引量：1

共引文献35

1Andrew Walcott Beckwith.Initial Mass in Pre-Planckian Space-Timed Defined, and Causal Discontinuity[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(1):9-15.
2Andrew Walcott Beckwith.Examination of Schrodinger Equation in Pre-Planckian Space-Time Early Universe[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(1):21-28. 被引量：1
3Andrew Walcott Beckwith.Calculating &delta;gttat Boundary of Start of Planckian Physics Due to 1 Million Relic Black Holes[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(1):29-33.
4Andrew Walcott Beckwith.Examination of Sufficient Conditions for Forming Mass of “Massive Graviton”, from Early Universe[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(1):34-38. 被引量：1
5Andrew Walcott Beckwith.Examination of Minimum Time Step, from Modified Heisenberg Uncertainty Principle, Inflaton Physics and Black Hole Physics[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(1):39-45.
6Andrew Walcott Beckwith.Does GW Generation Have Semi-Classical Features?[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(1):46-61.
7Andrew Walcott Beckwith.Examination of h(x) Real Field of Higgs Boson as Originating in Pre-Planckian Space-Time Early Universe[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(1):62-67.
8Andrew Walcott Beckwith.Part 2: Review of Tokamak Physics as a Way to Construct a Device Optimal for Graviton Detection and Generation within a Confined Small Spatial Volume, as Opposed to Dyson’s “Infinite Astrophysical Volume” Calculations[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(1):138-155. 被引量：2
9Andrew Walcott Beckwith.Creating a (Quantum?) Constraint, in Pre Planckian Space-Time Early Universe via the Einstein Cosmological Constant in a One to One and Onto Comparison between Two Action Integrals[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(2):167-172. 被引量：5
10Andrew Walcott Beckwith.Lowest Order Mass of KK Graviton Revisited and How It May Affect the Blue Spectrum for Gravitons[J].Journal of High Energy Physics, Gravitation and Cosmology,2017,3(2):296-307.

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Journal of High Energy Physics, Gravitation and Cosmology

2023年第1期

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Using “Particle Density” of “Graviton Gas”, to Obtain Value of Cosmological Constant

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