Ether Physics as Unified Framework

[1] Einstein, A. (1905). Zur Elektrodynamik bewegter Körper. Annalen der Physik, 17, 891–921.

[2] Lamoreaux, S.K. (1997). Demonstration of the Casimir Force in the 0.6 to 6 μm Range. Physical Review Letters, 78(1), 5–9.

[3] Hanneke, D., Fogwell, S. & Gabrielse, G. (2008). New Measurement of the Electron Magnetic Moment and the Fine Structure Constant. Physical Review Letters, 100(12), 120801.

[4] Mohideen, U. & Roy, A. (1998). Precision Measurement of the Casimir Force from 0.1 to 0.9 μm. Physical Review Letters, 81(21), 4549–4552.

[5] Lamb, W.E. & Retherford, R.C. (1947). Fine Structure of the Hydrogen Atom by a Microwave Method. Physical Review, 72(3), 241–243.

[6] Milonni, P.W. (1994). The Quantum Vacuum: An Introduction to Quantum Electrodynamics. Academic Press.

[7] Planck Collaboration (2020). Planck 2018 Results. VI. Cosmological Parameters. Astronomy & Astrophysics, 641, A6.

[8] LIGO Scientific Collaboration & Virgo Collaboration (2016). Observation of Gravitational Waves from a Binary Black Hole Merger. Physical Review Letters, 116(6), 061102.

[9] Dirac, P.A.M. (1951). Is There an Aether? Nature, 168, 906–907.

[10] Unruh, W.G. (1981). Experimental Black-Hole Evaporation? Physical Review Letters, 46, 1351–1353.

[11] Visser, M. (1998). Acoustic Black Holes: Horizons, Ergospheres, and Hawking Radiation. Classical and Quantum Gravity, 15, 1767–1791.

[12] Lorentz, H.A. (1904). Electromagnetic Phenomena in a System Moving with Any Velocity Smaller than that of Light. Proceedings of the Royal Netherlands Academy of Arts and Sciences, 6, 809–831.

[13] Poincaré, H. (1905). Sur la dynamique de l'électron. Comptes Rendus de l'Académie des Sciences, 140, 1504–1508.

[14] Brown, H.R. (2005). Physical Relativity: Space-time Structure from a Dynamical Perspective. Oxford University Press.

[15] Acuña, P. (2014). On the Empirical Equivalence Between Special Relativity and Lorentz's Ether Theory. Studies in History and Philosophy of Modern Physics, 46(B), 283–302.

[16] Boyer, T.H. (1969). Derivation of the Blackbody Radiation Spectrum without Quantum Assumptions. Physical Review, 182(5), 1374–1383.

[17] de la Peña, L. & Cetto, A.M. (1996). The Quantum Dice: An Introduction to Stochastic Electrodynamics. Kluwer Academic Publishers.

[18] de la Peña, L., Cetto, A.M. & Valdés-Hernández, A. (2014). The Emerging Quantum: The Physics Behind Quantum Mechanics. Springer.

[19] Nelson, E. (1966). Derivation of the Schrödinger Equation from Newtonian Mechanics. Physical Review, 150, 1079–1085.

[20] Michelson, A.A. & Morley, E.W. (1887). On the Relative Motion of the Earth and the Luminiferous Ether. American Journal of Science, 34(203), 333–345.

[21] Kennedy, R.J. & Thorndike, E.M. (1932). Experimental Establishment of the Relativity of Time. Physical Review, 42(3), 400–418.

[22] Müller, H., Herrmann, S., Braxmaier, C., Schiller, S. & Peters, A. (2003). Modern Michelson-Morley Experiment using Cryogenic Optical Resonators. Physical Review Letters, 91(2), 020401.

[23] Aprile, E. et al. [XENON Collaboration] (2023). First Dark Matter Search with Nuclear Recoils from the XENONnT Experiment. Physical Review Letters, 131(4), 041003.

[24] Weinberg, S. (1989). The Cosmological Constant Problem. Reviews of Modern Physics, 61(1), 1–23.

[25] Schlosshauer, M. (2005). Decoherence, the Measurement Problem, and Interpretations of Quantum Mechanics. Reviews of Modern Physics, 76(4), 1267–1305.

[26] Kiefer, C. (2007). Quantum Gravity (2nd ed.). Oxford University Press.

[27] Young, T. (1802). The Bakerian Lecture: On the Theory of Light and Colours. Philosophical Transactions of the Royal Society of London, 92, 12–48.

[28] Fresnel, A.J. (1818). Lettre d'Augustin Fresnel à François Arago sur l'influence du mouvement terrestre dans quelques phénomènes d'optique. Annales de Chimie et de Physique, 9, 57–66.

[29] Fizeau, H. (1851). Sur les hypothèses relatives à l'éther lumineux. Comptes Rendus de l'Académie des Sciences, 33, 349–355.

[30] Maxwell, J.C. (1865). A Dynamical Theory of the Electromagnetic Field. Philosophical Transactions of the Royal Society of London, 155, 459–512.

[31] Lorentz, H.A. (1895). Versuch einer Theorie der electrischen und optischen Erscheinungen in bewegten Körpern. Leiden: E.J. Brill.

[32] Poincaré, H. (1906). Sur la dynamique de l'électron. Rendiconti del Circolo Matematico di Palermo, 21, 129–176.

[33] Minkowski, H. (1908). Die Grundgleichungen für die elektromagnetischen Vorgänge in bewegten Körpern. Nachrichten von der Königlichen Gesellschaft der Wissenschaften zu Göttingen, 53–111.

[34] Janssen, M. (1995). A Comparison Between Lorentz's Ether Theory and Special Relativity in the Light of the Experiments of Trouton and Noble. PhD Thesis, University of Pittsburgh.

[35] Barceló, C., Liberati, S. & Visser, M. (2005). Analogue Gravity. Living Reviews in Relativity, 8, 12.

[36] Painlevé, P. (1921). La mécanique classique et la théorie de la relativité. Comptes Rendus de l'Académie des Sciences, 173, 677–680.

[37] Gullstrand, A. (1922). Allgemeine Lösung des statischen Einkörperproblems in der Einsteinschen Gravitationstheorie. Arkiv för Matematik, Astronomi och Fysik, 16(8), 1–15.

[38] Hamilton, A.J.S. & Lisle, J.P. (2008). The River Model of Black Holes. American Journal of Physics, 76, 519–532.

[39] Pound, R.V. & Rebka, G.A. (1960). Apparent Weight of Photons. Physical Review Letters, 4(7), 337–341.

[40] Vessot, R.F.C. et al. (1980). Test of Relativistic Gravitation with a Space-Borne Hydrogen Maser. Physical Review Letters, 45(26), 2081–2084.

[41] Bothwell, T. et al. (2022). Resolving the Gravitational Redshift Across a Millimetre-Scale Atomic Sample. Nature, 602, 420–424.

[42] Dyson, F.W., Eddington, A.S. & Davidson, C. (1920). A Determination of the Deflection of Light by the Sun's Gravitational Field. Philosophical Transactions of the Royal Society A, 220, 291–333.

[43] Shapiro, S.S. et al. (2004). Measurement of the Solar Gravitational Deflection of Radio Waves Using Geodetic Very-Long-Baseline Interferometry Data. Physical Review Letters, 92(12), 121101.

[44] Shapiro, I.I. (1964). Fourth Test of General Relativity. Physical Review Letters, 13(26), 789–791.

[45] Bertotti, B., Iess, L. & Tortora, P. (2003). A Test of General Relativity Using Radio Links with the Cassini Spacecraft. Nature, 425, 374–376.

[46] Park, R.S. et al. (2017). Precession of Mercury's Perihelion from Ranging to the MESSENGER Spacecraft. The Astronomical Journal, 153(3), 121.

[47] Abbott, B.P. et al. [LIGO Scientific Collaboration & Virgo Collaboration] (2017). Gravitational Waves and Gamma-Rays from a Binary Neutron Star Merger: GW170817 and GRB 170817A. The Astrophysical Journal Letters, 848(2), L13.

[48] Abbott, B.P. et al. (2019). Tests of General Relativity with the Binary Black Hole Signals from the LIGO-Virgo Catalog GWTC-1. Physical Review D, 100(10), 104036.

[49] Liberati, S. (2013). Tests of Lorentz Invariance: A 2013 Update. Classical and Quantum Gravity, 30, 133001.

[50] Mattingly, D. (2005). Modern Tests of Lorentz Invariance. Living Reviews in Relativity, 8, 5.

[51] Abdo, A.A. et al. [Fermi-LAT Collaboration] (2009). A Limit on the Variation of the Speed of Light Arising from Quantum Gravity Effects. Nature, 462, 331–334.

[52] MAGIC Collaboration (2020). Bounds on Lorentz Invariance Violation from MAGIC Observation of GRB 190114C. Physical Review Letters, 125(2), 021301.

[53] Cherenkov Telescope Array Consortium (2019). Science with the Cherenkov Telescope Array. World Scientific.

[54] Kogut, A. et al. (1993). Dipole Anisotropy in the COBE Differential Microwave Radiometers First-Year Sky Maps. The Astrophysical Journal, 419, 1–6.

[57] Aalbers, J. et al. [LZ Collaboration] (2023). First Dark Matter Search Results from the LUX-ZEPLIN (LZ) Experiment. Physical Review Letters, 131(4), 041002.

[58] Meng, Y. et al. [PandaX-4T Collaboration] (2021). Dark Matter Search Results from the PandaX-4T Commissioning Run. Physical Review Letters, 127(26), 261802.

[59] Bekenstein, J. & Milgrom, M. (1984). Does the Missing Mass Problem Signal the Breakdown of Newtonian Gravity? The Astrophysical Journal, 286, 7–14.

[60] McGaugh, S.S., Lelli, F. & Schombert, J.M. (2016). Radial Acceleration Relation in Rotationally Supported Galaxies. Physical Review Letters, 117(20), 201101.

[61] Lelli, F., McGaugh, S.S. & Schombert, J.M. (2016). SPARC: Mass Models for 175 Disk Galaxies with Spitzer Photometry and Accurate Rotation Curves. The Astronomical Journal, 152(6), 157.

[62] Desmond, H. (2017). A Statistical Investigation of the Mass Discrepancy–Acceleration Relation. Monthly Notices of the Royal Astronomical Society, 464(4), 4160–4175.

[64] Clowe, D. et al. (2006). A Direct Empirical Proof of the Existence of Dark Matter. The Astrophysical Journal Letters, 648(2), L109–L113.

[67] Milgrom, M. (1983). A Modification of the Newtonian Dynamics as a Possible Alternative to the Hidden Mass Hypothesis. The Astrophysical Journal, 270, 365–370.

[68] Bekenstein, J.D. (2004). Relativistic Gravitation Theory for the Modified Newtonian Dynamics Paradigm. Physical Review D, 70(8), 083509.

[69] Milgrom, M. (1999). The Modified Dynamics as a Vacuum Effect. Physics Letters A, 253(5–6), 273–279.

[70] Adelberger, E.G., Heckel, B.R. & Nelson, A.E. (2003). Tests of the Gravitational Inverse-Square Law. Annual Review of Nuclear and Particle Science, 53, 77–121.

[71] Berezhiani, L. & Khoury, J. (2015). Theory of Dark Matter Superfluidity. Physical Review D, 92(10), 103510.

[73] Pethick, C.J. & Smith, H. (2008). Bose–Einstein Condensation in Dilute Gases (2nd ed.). Cambridge University Press.

[75] Khalatnikov, I.M. (2000). An Introduction to the Theory of Superfluidity. Westview Press.

[76] Pitaevskii, L. & Stringari, S. (2016). Bose–Einstein Condensation and Superfluidity (2nd ed.). Oxford University Press.

[77] Sanders, R.H. (2003). Clusters of Galaxies with Modified Newtonian Dynamics. Monthly Notices of the Royal Astronomical Society, 342(3), 901–908.

[78] Sarazin, C.L. (1988). X-Ray Emission from Clusters of Galaxies. Cambridge University Press.

[79] Markevitch, M. et al. (2004). Direct Constraints on the Dark Matter Self-Interaction Cross Section from the Merging Galaxy Cluster 1E 0657-56. The Astrophysical Journal, 606(2), 819–824.

[80] Bradač, M. et al. (2006). Strong and Weak Lensing United. III. Measuring the Mass Distribution of the Merging Galaxy Cluster 1ES 0657-558. The Astrophysical Journal, 652(2), 937–947.

[81] Jee, M.J. et al. (2014). HST/ACS Confirmation of the Dark Substructure in Abell 520. The Astrophysical Journal, 783(2), 78.

[82] Gonzalez, A.H., Zaritsky, D. & Zabludoff, A.I. (2007). A Census of Baryons in Galaxy Clusters and Groups. The Astrophysical Journal, 666(1), 147–155.

[84] Bogoliubov, N.N. (1947). On the Theory of Superfluidity. Journal of Physics USSR, 11, 23–32.

[85] Marshall, T.W. (1963). Random Electrodynamics. Proceedings of the Royal Society A, 276(1367), 475–491.

[86] Boyer, T.H. (1969). Derivation of the Blackbody Radiation Spectrum without Quantum Assumptions. Physical Review, 182(5), 1374–1383.

[87] Milonni, P.W. (1994). The Quantum Vacuum: An Introduction to Quantum Electrodynamics. Academic Press.

[88] Sedmik, R.I.P. & Pitschmann, M. (2021). Next Generation Design and Prospects for Cannex. Universe, 7(7), 234.

[89] de la Peña, L. & Cetto, A.M. (1996). The Quantum Dice: An Introduction to Stochastic Electrodynamics. Kluwer Academic Publishers.

[90] de la Peña, L., Cetto, A.M. & Hernández, A.V. (2015). The Emerging Quantum: The Physics Behind Quantum Mechanics. Springer.

[91] Puthoff, H.E. (1987). Ground State of Hydrogen as a Zero-Point-Fluctuation-Determined State. Physical Review D, 35(10), 3266–3269.

[92] Cole, D.C. & Zou, Y. (2003). Quantum Mechanical Ground State of Hydrogen Obtained from Classical Electrodynamics. Physics Letters A, 317(1–2), 14–20.

[93] Casimir, H.B.G. (1948). On the Attraction Between Two Perfectly Conducting Plates. Proceedings of the Koninklijke Nederlandse Akademie van Wetenschappen, 51, 793–795.

[94] Lamoreaux, S.K. (1997). Demonstration of the Casimir Force in the 0.6 to 6 μm Range. Physical Review Letters, 78(1), 5–9.

[95] Larraza, A., Denardo, B. & Putterman, S. (1998). An Acoustic Casimir Effect. Physics Letters A, 248(2–4), 151–155.

[96] Mohideen, U. & Roy, A. (1998). Precision Measurement of the Casimir Force from 0.1 to 0.9 μm. Physical Review Letters, 81(21), 4549–4552.

[97] Bressi, G. et al. (2002). Measurement of the Casimir Force Between Parallel Metallic Surfaces. Physical Review Letters, 88(4), 041804.

[98] Decca, R.S. et al. (2003). Measurement of the Casimir Force Between Dissimilar Metals. Physical Review Letters, 91(5), 050402.

[99] Boyer, T.H. (1973). Retarded Van der Waals Forces at All Distances Derived from Classical Electrodynamics with Classical Electromagnetic Zero-Point Radiation. Physical Review A, 7(6), 1832–1840.

[100] Nelson, E. (1966). Derivation of the Schrödinger Equation from Newtonian Mechanics. Physical Review, 150(4), 1079–1085.

[101] Nelson, E. (1985). Quantum Fluctuations. Princeton University Press.

[102] Carlen, E. (1984). Conservative Diffusions. Communications in Mathematical Physics, 94(3), 293–315.

[103] Bacciagaluppi, G. (1999). Nelsonian Mechanics Revisited. Foundations of Physics Letters, 12(1), 1–16.

[104] Bell, J.S. (1964). On the Einstein Podolsky Rosen Paradox. Physics, 1(3), 195–200.

[107] Cetto, A.M., de la Peña, L. & Valdés-Hernández, A. (2012). Quantization as an Emergent Phenomenon Due to Matter–ZPF Interaction. Journal of Physics: Conference Series, 361, 012013.

[111] Serva, M. (1988). Relativistic Stochastic Processes Associated to Klein–Gordon Equation. Annales de l'Institut Henri Poincaré, 49(4), 415–432.

[112] Gardiner, C.W. (2009). Stochastic Methods: A Handbook for the Natural and Social Sciences. 4th ed. Springer.

[113] Bohm, D. (1952). A Suggested Interpretation of the Quantum Theory in Terms of "Hidden" Variables. Physical Review, 85(2), 166–179.

[115] Clauser, J.F., Horne, M.A., Shimony, A. & Holt, R.A. (1969). Proposed Experiment to Test Local Hidden-Variable Theories. Physical Review Letters, 23(15), 880–884.

[116] Tsirelson, B.S. (1980). Quantum Generalizations of Bell's Inequality. Letters in Mathematical Physics, 4(2), 93–100.

[117] Aspect, A., Dalibard, J. & Roger, G. (1982). Experimental Test of Bell's Inequalities Using Time-Varying Analyzers. Physical Review Letters, 49(25), 1804–1807.

[118] Hensen, B. et al. (2015). Loophole-Free Bell Inequality Violation Using Electron Spins Separated by 1.3 Kilometres. Nature, 526(7575), 682–686.

[119] Giustina, M. et al. (2015). Significant-Loophole-Free Test of Bell's Theorem with Entangled Photons. Physical Review Letters, 115(25), 250401.

[120] Walls, D.F. & Milburn, G.J. (2008). Quantum Optics. 2nd ed. Springer.

[121] Gardiner, C.W. & Zoller, P. (2004). Quantum Noise: A Handbook of Markovian and Non-Markovian Quantum Stochastic Methods. 3rd ed. Springer.

[122] Duan, L.-M., Giedke, G., Cirac, J.I. & Zoller, P. (2000). Inseparability Criterion for Continuous Variable Systems. Physical Review Letters, 84(12), 2722–2725.

[123] Simon, R. (2000). Peres–Horodecki Separability Criterion for Continuous Variable Systems. Physical Review Letters, 84(12), 2726–2729.

[124] Peres, A. (1996). Separability Criterion for Density Matrices. Physical Review Letters, 77(8), 1413–1415.

[125] Banaszek, K. & Wódkiewicz, K. (1998). Nonlocality of the Einstein-Podolsky-Rosen State in the Wigner Representation. Physical Review A, 58(6), 4345–4347.

[126] Bell, J.S. (1987). Speakable and Unspeakable in Quantum Mechanics. Cambridge University Press, p. 196.

[127] Wenger, J., Hafezi, M., Grosshans, F., Tualle-Brouri, R. & Grangier, P. (2003). Maximal Violation of Bell Inequalities Using Continuous-Variable Measurements. Physical Review A, 67(1), 012105.

[128] Cole, D.C. & Zou, Y. (2003). Quantum Mechanical Ground State of Hydrogen Obtained from Classical Electrodynamics. Physics Letters A, 317(1–2), 14–20.

[129] Nieuwenhuizen, T.M. & Liska, M.T.P. (2015). Simulation of the Hydrogen Ground State in Stochastic Electrodynamics. Physica Scripta, T165, 014006.

[130] Ghirardi, G.C., Rimini, A. & Weber, T. (1980). A General Argument Against Superluminal Transmission Through the Quantum Mechanical Measurement Process. Lettere al Nuovo Cimento, 27(10), 293–298.

[131] Adesso, G. & Illuminati, F. (2007). Entanglement in Continuous-Variable Systems. Journal of Physics A, 40(28), 7821–7880.

[132] Storz, S. et al. (2023). Loophole-Free Bell Inequality Violation with Superconducting Circuits. Nature, 617, 265–270.

[133] Sheppard, W.F. (1899). On the Application of the Theory of Error to Cases of Normal Distribution and Normal Correlation. Philosophical Transactions of the Royal Society A, 192, 101–167.

[134] Werner, R.F. (1989). Quantum States with Einstein-Podolsky-Rosen Correlations Admitting a Hidden-Variable Model. Physical Review A, 40(8), 4277–4281.

[135] Breuer, H.-P. & Petruccione, F. (2007). The Theory of Open Quantum Systems. Oxford University Press.

[136] Li, P., Lelli, F., McGaugh, S. & Schombert, J. (2018). Fitting the Radial Acceleration Relation to Individual SPARC Galaxies. Astronomy & Astrophysics, 615, A3.

[137] Famaey, B. & Binney, J. (2005). Modified Newtonian Dynamics in the Milky Way. Monthly Notices of the Royal Astronomical Society, 363(2), 603–608.

[138] Milgrom, M. (1983). A Modification of the Newtonian Dynamics as a Possible Alternative to the Hidden Mass Hypothesis. The Astrophysical Journal, 270, 365–370.

[139] Keller, B.W. & Wadsley, J.W. (2017). $\Lambda$ CDM is Consistent with SPARC Radial Acceleration Relation. The Astrophysical Journal Letters, 835(1), L17.

[140] Dawson, W.A. et al. (2012). Discovery of a Dissociative Galaxy Cluster Merger with Large Physical Separation. The Astrophysical Journal Letters, 747(2), L42.

[141] Bradač, M. et al. (2008). Revealing the Properties of Dark Matter in the Merging Cluster MACS J0025.4−1222. The Astrophysical Journal, 687(2), 959–967.

[142] Long, J.C. et al. (2003). Upper Limits to Submillimetre-Range Forces from Extra Space-Time Dimensions. Nature, 421, 922–925.

[143] Milgrom, M. (2019). MOND in Galaxy Groups. Physical Review D, 99(4), 044041.

[144] Tian, Y. & Ko, C.-M. (2017). Dynamics of Elliptical Galaxies with Planetary Nebulae in Modified Newtonian Dynamics. Monthly Notices of the Royal Astronomical Society, 472(1), 765–774.

[145] Chen, F.F. (2016). Introduction to Plasma Physics and Controlled Fusion (3rd ed.). Springer.

[146] Bellan, P.M. (2006). Fundamentals of Plasma Physics. Cambridge University Press.

[147] Stix, T.H. (1992). Waves in Plasmas. American Institute of Physics.

[148] Euler, H. & Heisenberg, W. (1936). Folgerungen aus der Diracschen Theorie des Positrons. Zeitschrift für Physik, 98, 714–732.

[149] Landau, L.D. (1946). On the Vibrations of the Electronic Plasma. Journal of Physics (USSR), 10(1), 25–34.

[150] Klimontovich, Yu.L. (1982). Statistical Physics. Harwood Academic Publishers.

[151] Peters, P.C. (1964). Gravitational Radiation and the Motion of Two Point Masses. Physical Review, 136(4B), B1224–B1232.

[152] Weisberg, J.M. & Huang, Y. (2016). Relativistic Measurements from Timing the Binary Pulsar PSR B1913+16. The Astrophysical Journal, 829(1), 55.

[153] Volovik, G.E. (2003). The Universe in a Helium Droplet. Oxford University Press.