|
|
Publications in Math-Net.Ru |
Citations |
|
2022 |
1. |
G. B. Malykin, “Corrigenda and addition to the paper by Malykin G B “Application of the modified Duguay method for measuring the Lorentz contraction of a moving body length”, Usp. Fiz. Nauk, October 2022, Vol. 191, No. 10, p. 1117–1121”, UFN, 192:2 (2022), 232 |
|
2021 |
2. |
G. B. Malykin, “The history of the development of methods and interference devices for measuring small optical phase differences (overview)”, Optics and Spectroscopy, 129:2 (2021), 174–188 ; Optics and Spectroscopy, 129:2 (2021), 212–226 |
3. |
G. B. Malykin, “Application of the modified Duguay method for measuring the Lorentz contraction of a moving body length”, UFN, 191:10 (2021), 1117–1121 ; Phys. Usp., 64:10 (2021), 1058–1062 |
|
2020 |
4. |
G. B. Malykin, V. I. Pozdnyakova, “Quadratic Sagnac effect recorded by an observer in the laboratory frame”, Optics and Spectroscopy, 128:10 (2020), 1501–1506 ; Optics and Spectroscopy, 128:10 (2020), 1611–1617 |
5. |
G. B. Malykin, V. I. Pozdnyakova, “Linear transformation of polarization modes in coiled optical spun fibers. III. Approximate analytic presentation”, Optics and Spectroscopy, 128:1 (2020), 68–75 ; Optics and Spectroscopy, 128:1 (2020), 66–73 |
|
2019 |
6. |
G. B. Malykin, V. I. Pozdnyakova, “Exact solutions for the local parameters of polarization modes in coiled optical spun fibers with strong unperturbed linear birefringence.
I. Nonresonant linear transformation”, Optics and Spectroscopy, 127:6 (2019), 937–941 ; Optics and Spectroscopy, 127:6 (2019), 1028–1031 |
1
|
7. |
B. M. Bolotovskii, G. B. Malykin, “Visible shape of moving bodies”, UFN, 189:10 (2019), 1084–1103 ; Phys. Usp., 62:10 (2019), 1012–1030 |
2
|
|
2018 |
8. |
G. B. Malykin, V. I. Pozdnyakova, “Linear transformation of the polarization modes in coiled optical spun fibers II. Resonant transformation”, Optics and Spectroscopy, 125:4 (2018), 522–529 ; Optics and Spectroscopy, 125:4 (2018), 543–550 |
4
|
9. |
G. B. Malykin, V. I. Pozdnyakova, “Linear transformation of the polarization modes in coiled optical spun-fibers with strong unperturbed linear birefringence. I. Nonresonant transformation”, Optics and Spectroscopy, 124:3 (2018), 359–370 ; Optics and Spectroscopy, 124:3 (2018), 360–372 |
6
|
|
2016 |
10. |
V. G. Veselago, E. M. Dianov, V. N. Kuryatov, G. B. Malykin, O. D. Volpyan, “On the possibility of using metamaterials in a ring laser gyroscope”, Kvantovaya Elektronika, 46:6 (2016), 543–544 [Quantum Electron., 46:6 (2016), 543–544 ] |
11. |
G. B. Malykin, “V L Ginzburg's helical elliptically polarized modes and their application”, UFN, 186:12 (2016), 1355–1358 ; Phys. Usp., 59:12 (2016), 1245–1248 |
4
|
12. |
G. B. Malykin, V. I. Pozdnyakova, “Inconsistencies in the work of P Maraner (reply to comment [Usp. Fiz. Nauk 186 795 (2016)] on the paper “Quadratic Sagnac effect — the influence of gravitational potential of Coriolis force on the phase difference between the arms of a rotating Michelson interferometer (an explanation of D C Miller's experimental results, 1921–1926)” (Usp. Fiz. Nauk 185 431 (2015) [Phys. Usp. 58 398 (2015)])”, UFN, 186:7 (2016), 796–798 ; Phys. Usp., 59:7 (2016), 719–721 |
2
|
|
2015 |
13. |
G. B. Malykin, V. I. Pozdnyakova, “Supplement to the paper “Quadratic Sagnac effect — the influence of the gravitational potential of the Coriolis force on the phase difference between the arms of a rotating Michelson interferometer (an explanation of D C Miller's experimental results, 1921 – 1926)” (Usp. Fiz. Nauk 185 431 (2015) [Phys. Usp. 58 398 (2015)])”, UFN, 185:8 (2015), 895–896 ; Phys. Usp., 58:8 (2015), 828–829 |
3
|
14. |
G. B. Malykin, V. I. Pozdnyakova, “Quadratic Sagnac effect — the influence of the gravitational potential of the Coriolis force on the phase difference between the arms of a rotating Michelson interferometer (an explanation of D C Miller's experimental results, 1921–1926)”, UFN, 185:4 (2015), 431–440 ; Phys. Usp., 58:4 (2015), 398–406 |
10
|
|
2014 |
15. |
G. B. Malykin, “Sagnac effect in ring lasers and ring resonators. How does the refractive index of the optical medium influence the sensitivity to rotation?”, UFN, 184:7 (2014), 775–781 ; Phys. Usp., 57:7 (2014), 714–720 |
28
|
|
2009 |
16. |
G. B. Malykin, “Paralorentz transformations”, UFN, 179:3 (2009), 285–288 ; Phys. Usp., 52:3 (2009), 263–266 |
12
|
|
2006 |
17. |
G. B. Malykin, “Thomas precession: correct and incorrect solutions”, UFN, 176:8 (2006), 865–882 ; Phys. Usp., 49:8 (2006), 837–853 |
48
|
|
2004 |
18. |
G. B. Malykin, “On the possibility of experimental verifying the second postulate of special relativity”, UFN, 174:7 (2004), 801–804 ; Phys. Usp., 47:7 (2004), 739–742 |
11
|
19. |
G. B. Malykin, V. I. Pozdnyakova, “Geometric phases in singlemode fiber lightguides and fiber ring interferometers”, UFN, 174:3 (2004), 303–322 ; Phys. Usp., 47:3 (2004), 289–308 |
24
|
|
2003 |
20. |
G. B. Malykin, S. A. Kharlamov, “Topological phase in classical mechanics”, UFN, 173:9 (2003), 985–994 ; Phys. Usp., 46:9 (2003), 957–965 |
16
|
|
2002 |
21. |
G. B. Malykin, “Sagnac effect in a rotating frame of reference. Relativistic Zeno paradox”, UFN, 172:8 (2002), 969–970 ; Phys. Usp., 45:8 (2002), 907–909 |
42
|
22. |
I. A. Andronova, G. B. Malykin, “Physical problems of fiber gyroscopy based on the Sagnac effect”, UFN, 172:8 (2002), 849–873 ; Phys. Usp., 45:8 (2002), 793–817 |
94
|
|
2000 |
23. |
G. B. Malykin, “The Sagnac effect: correct and incorrect explanations”, UFN, 170:12 (2000), 1325–1349 ; Phys. Usp., 43:12 (2000), 1229–1252 |
224
|
|
1999 |
24. |
I. A. Andronova, G. V. Gelikonov, G. B. Malykin, “Characteristic features of the effects of the polarisation nonreciprocity of fibre ring interferometers”, Kvantovaya Elektronika, 26:3 (1999), 271–275 [Quantum Electron., 29:3 (1999), 271–275 ] |
22
|
25. |
G. B. Malykin, “The relation of Thomas precession to Ishlinskii's theorem as applied to the rotating image of a relativistically moving body”, UFN, 169:5 (1999), 585–590 ; Phys. Usp., 42:5 (1999), 505–509 |
16
|
|
1997 |
26. |
G. B. Malykin, “Earlier studies of the Sagnac effect”, UFN, 167:3 (1997), 337–342 ; Phys. Usp., 40:3 (1997), 317–321 |
46
|
|
1985 |
27. |
V. M. Gelikonov, Yu. I. Zaĭtsev, G. B. Malykin, “Investigation of frequency resonance of a saturated methane transition in He–Ne/CH<sub>4</sub> laser radiation with modulation of the resonator length”, Kvantovaya Elektronika, 12:11 (1985), 2357–2359 [Sov J Quantum Electron, 15:11 (1985), 1557–1558 ] |
|
1984 |
28. |
V. M. Gelikonov, Yu. I. Zaĭtsev, G. B. Malykin, “Determination of the relaxation constants of a nonlinearly absorbing gas using a frequency-modulated laser”, Kvantovaya Elektronika, 11:3 (1984), 519–523 [Sov J Quantum Electron, 14:3 (1984), 353–355 ] |
|
1983 |
29. |
V. M. Gelikonov, G. B. Malykin, “Natural fluctuations of the emission frequency of an He–Ne/CH<sub>4</sub> 3.39 μ laser”, Kvantovaya Elektronika, 10:1 (1983), 145–149 [Sov J Quantum Electron, 13:1 (1983), 85–88 ] |
2
|
|
1979 |
30. |
V. M. Gelikonov, Yu. I. Zaĭtsev, G. B. Malykin, “Laser frequency self-stabilization effect in the presence of rapid perturbations”, Kvantovaya Elektronika, 6:2 (1979), 381–383 [Sov J Quantum Electron, 9:2 (1979), 227–229] |
|
|
|
2012 |
31. |
G. B. Malykin, V. S. Savchuk, E. A. Romanets (Shcherbak), “Lev Yakovlevich Strum and the hypothesis of the existence of tachyons”, UFN, 182:11 (2012), 1217–1222 ; Phys. Usp., 55:11 (2012), 1134–1139 |
5
|
|
2010 |
32. |
G. B. Malykin, “Noncommutative nature of the addition of noncollinear velocities in special relativity and the geometric phase method (commemorating the publication centennial of A. Sommerfeld's work)”, UFN, 180:9 (2010), 965–969 ; Phys. Usp., 53:9 (2010), 923–927 |
2
|
|
2009 |
33. |
G. B. Malykin, “Errata and amendments”, UFN, 179:4 (2009), 442 |
2
|
|
Organisations |
|
|
|
|