| Предварительный просмотр | Дата выпуска | Заглавие | Автор(ы) |
| 2019 | Comment on "new proof of general relativity through the correct physical interpretation of the Mössbauer rotor experiment" by C. Corda | Kholmetskii, A. L.; Yarman, T.; Yarman, O.; Arik, M. |
| 2021 | Comparison of traditional and synchrotron beam methodologies in Mössbauer experiments in a rotating system | Kholmetskii, A.L.; Yarman, T.; Yarman, O.; Arik, M. |
| 2019 | Concerning Mössbauer experiments in a rotating system and their physical interpretation | Kholmetskii, A.L.; Yarman, T.; Yarman, O.; Arik, M. |
| 2021 | Corrigendum to “Quantum phases for point-like charged particles and for electrically neutral dipoles in an electromagnetic field” [Ann. Phys. 392 (2018) 49–62](S0003491618300605)(10.1016/j.aop.2018.03.005) | Kholmetskii, A.L.; Missevitch, O.V.; Yarman, T. |
| 2021 | Doppler effect in rotating systems and Mössbauer rotor experiments | Kholmetskii, A.L.; Yarman, T.; Yarman, O.; Arik, M. |
| 2016 | Force law in material media and quantum phases | Kholmetskii, A.; Missevitch, O.; Yarman, T. |
| дек-2020 | Frequency difference between two clocks at Tokyo Skytree: Contribution of Earth’s self-rotation | Yarman, T.; Kholmetskii, A.L.; Yarman, O.; Arik, M. |
| 2022 | Klein-Gordon equation for electrically charged particles with new energy-momentum operator | Kholmetskii, A.L.; Yarman, T.; Missevitch, O.V. |
| 2019 | LIGO's "gW150914 signal" reproduced under YARK theory of gravity | Yarman, T.; Kholmetskii, A.L.; Yarman, O.; Marchal, C.B.; Arik, M. |
| 2021 | Mössbauer experiments in a rotating system and physical interpretation of their results | Kholmetskii, A. L.; Yarman, T.; Yarman, O.; Arik, M. |
| 2016 | Novel Mössbauer experiment in a rotating system and the extra-energy shift between emission and absorption lines | Yarman, T.; Kholmetskii, A.L.; Arik, M.; Akkus, B.; Oktem, Y.; Susam, L.A.; Missevitch, O.V. |
| июн-2023 | Quantal Theory of Gravity (QTG): Essential points and implications | Kholmetskii, A.L; Yarman, T.; Marchal, С.V.; Yarman, O. |
| 2022 | Quantum phase effects for electrically charged particles and redefinition of the momentum operator | Kholmetskii, A.L.; Yarman, T.; Missevitch, O.V. |
| 2022 | Quantum phase effects for electrically charged particles and redefinition of the momentum operator | Kholmetskii, A.L.; Yarman, T.; Missevitch, O.V. |
| 2022 | Quantum phase effects for electrically charged particles: converging descriptions via fields and potentials | Kholmetskii, A.L.; Yarman, T.; Missevitch, O.V. |
| 2022 | Quantum phase effects for electrically charged particles: updated analysis | Kholmetskii, A.L.; Yarman, T.; Missevitch, O.V. |
| 2018 | Quantum phases for moving charges and dipoles in an electromagnetic field and fundamental equations of quantum mechanics | Kholmetskii, A.L.; Yarman, T.; Missevitch, O.V.; Arik, M. |
| 2018 | Quantum phases for point-like charged particles and for electrically neutral dipoles in an electromagnetic field | Kholmetskii, A.L.; Missevitch, O.V.; Yarman, T. |
| мар-2023 | Redefinition of the energy-momentum operator: Motivation and implications | Kholmetskii, A.L; Yarman, T.; Missevitch, O.V. |
| 2021 | Reply to “Comment on 'Lorentz transformation of a charge- current density and “relativistic polarization” of a moving current loop'” by J. Franklin | Kholmetskii, A.L.; Yarman, T.; Missevitch, O.V. |
