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Publications in Math-Net.Ru |
Citations |
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2024 |
| 1. |
Метод отражений в задачах электростатики и теплопроводности плоскослоистых сред, состоящих из трех пленок
TVT, Forthcoming paper |
| 2. |
О решении задач электростатики и теплопроводности плоскослоистых сред, состоящих из двух пленок
TVT, Forthcoming paper |
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2023 |
| 3. |
A. B. Petrin, “Распределение электромагнитного поля в нанослое фоторезиста при фокусировке поверхностной плазмонной волны на нановершине сканирующего металлического микроострия”, TVT, 61:4 (2023), 497–513  |
| 4. |
A. B. Petrin, “Heat conduction problem for a nonstationary point heat source in a plane-layered medium”, TVT, 61:1 (2023), 118–129 ; High Temperature, 61:1 (2023), 108–118 |
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2022 |
| 5. |
A. B. Petrin, “On a fundamental solution to problems of electrostatics and heat conductunce for plane-layered media”, TVT, 60:5 (2022), 740–751  ; High Temperature, 60:5 (2022), 677–687 |
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2021 |
| 6. |
A. B. Petrin, “On the radiation of a surface source along the normal to the boundary of a half-space and a plane-layered structure”, Optics and Spectroscopy, 129:7 (2021), 903–920 ; Optics and Spectroscopy, 129:9 (2021), 979–996 |
| 7. |
A. B. Petrin, “On the theory of a flat lens from a material with negative refraction”, Optics and Spectroscopy, 129:1 (2021), 55–65 ; Optics and Spectroscopy, 129:1 (2021), 72–83 |
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2020 |
| 8. |
A. B. Petrin, “Radiation in the far zone of an elementary emitter located on the boundary of a plane layered structure”, Optics and Spectroscopy, 128:12 (2020), 1874–1888 ; Optics and Spectroscopy, 129:1 (2021), 56–71 |
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| 9. |
A. B. Petrin, “Elementary radiator located at the boundary or inside a layered structure”, Optics and Spectroscopy, 128:11 (2020), 1676–1693 ; Optics and Spectroscopy, 128:11 (2020), 1809–1827 |
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| 10. |
A. B. Petrin, “On the electron emission from the focal region of a symmetrically convergent surface plasmonic wave on the free surface of a metal film”, Optics and Spectroscopy, 128:8 (2020), 1179–1188 ; Optics and Spectroscopy, 128:8 (2020), 1211–1220 |
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2019 |
| 11. |
A. B. Petrin, “Comparative analysis of the sensitivity of optical sensors based on surface waves excited in the Kretschmann scheme”, Optics and Spectroscopy, 127:6 (2019), 1051–1056 ; Optics and Spectroscopy, 127:6 (2019), 1182–1187 |
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| 12. |
A. B. Petrin, “On the Goos–Hänchen effect in the case of excitation of surface waves in the Kretschmann scheme”, Optics and Spectroscopy, 127:4 (2019), 654–659 ; Optics and Spectroscopy, 127:4 (2019), 706–711 |
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| 13. |
A. B. Petrin, “On the focusing of surface plasmonic waves on the free surface of a metal film”, Optics and Spectroscopy, 126:3 (2019), 350–359 ; Optics and Spectroscopy, 126:3 (2019), 269–278 |
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| 14. |
A. B. Petrin, “On the nonlocality of the reflection of an electromagnetic wave from a flat surface upon excitation of surface waves”, Kvantovaya Elektronika, 49:3 (2019), 258–265 [Quantum Electron., 49:3 (2019), 258–265   ] |
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| 15. |
A. B. Petrin, “Nanofocusing of light on the apex of metal microtip located near multilayer thin film strucure: theory and possible applications”, TVT, 57:1 (2019), 20–25 ; High Temperature, 57:1 (2019), 17–21 |
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2018 |
| 16. |
A. B. Petrin, O. D. Volpyan, A. S. Sigov, “Excitation of surface waves in plane-layered structures and development of optical modulators”, Zhurnal Tekhnicheskoi Fiziki, 88:3 (2018), 433–437 ; Tech. Phys., 63:3 (2018), 422–426 |
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| 17. |
A. B. Petrin, “On surface wave excitation by of finite-aperture light beams”, Optics and Spectroscopy, 125:6 (2018), 830–837 ; Optics and Spectroscopy, 125:6 (2018), 1025–1033 |
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| 18. |
A. B. Petrin, “On diffraction phenomena in sensors of surface waves”, Optics and Spectroscopy, 125:3 (2018), 375–382 ; Optics and Spectroscopy, 125:3 (2018), 390–397 |
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| 19. |
A. B. Petrin, “Method for the calculation of the electric field near a paraboloidal metal tip above a conducting plane”, TVT, 56:2 (2018), 163–167 ; High Temperature, 56:2 (2018), 157–161 |
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2016 |
| 20. |
A. B. Petrin, “Focusing of light at the nanoapex of a metal microtip located above the plane of a dielectric or metal”, Kvantovaya Elektronika, 46:9 (2016), 848–854 [Quantum Electron., 46:9 (2016), 848–854 ] |
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| 21. |
A. B. Petrin, “Extremely tight focusing of light at the nanoapex of a metal microtip”, Kvantovaya Elektronika, 46:2 (2016), 159–162 [Quantum Electron., 46:2 (2016), 159–162 ] |
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| 22. |
A. B. Petrin, “Regularities of nanofocusing of a surface plasmon wave near the nanoapex of a metallic microtip”, TVT, 54:4 (2016), 500–507 ; High Temperature, 54:4 (2016), 475–482 |
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2015 |
| 23. |
A. B. Petrin, “Focusing of a surface plasmon wave at the apex of a metal microtip”, Kvantovaya Elektronika, 45:7 (2015), 658–662 [Quantum Electron., 45:7 (2015), 658–662 ] |
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2013 |
| 24. |
A. B. Petrin, “On the resolution of lenses made of a negative-index material”, Kvantovaya Elektronika, 43:9 (2013), 814–818 [Quantum Electron., 43:9 (2013), 814–818 ] |
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| 25. |
A. B. Petrin, “Notes on the microscopic theory of dielectric polarization”, TVT, 51:2 (2013), 170–175 ; High Temperature, 51:2 (2013), 147–152 |
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2012 |
| 26. |
A. B. Petrin, “Two regimes of nanofocusing of the surface plasmon-polariton wave at the vertex of the metal micropoint”, TVT, 50:1 (2012), 18–23 ; High Temperature, 50:1 (2012), 15–20 |
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2011 |
| 27. |
A. B. Petrin, “Heat Effect of Thermal-Field Emission of Electrons from Metal”, TVT, 49:4 (2011), 492–496 ; High Temperature, 49:4 (2011), 474–478 |
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| 28. |
A. B. Petrin, “Singularity of the Electric Field at the Wetting Line of a Dielectric Surface”, TVT, 49:1 (2011), 23–27 ; High Temperature, 49:1 (2011), 22–26 |
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2010 |
| 29. |
A. B. Petrin, “Thermionic-field emission of electrons from conical metal points”, TVT, 48:3 (2010), 323–332 ; High Temperature, 48:3 (2010), 305–314 |
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2009 |
| 30. |
A. B. Petrin, “The instability which leads to the splitting of a conducting liquid cylinder by the current flowing through”, TVT, 47:4 (2009), 498–505 ; High Temperature, 47:4 (2009), 472–479 |
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2008 |
| 31. |
A. B. Petrin, “Electromagnetic wave propagation from a point source in air through a medium with a negative refractive index”, Pis'ma v Zh. Èksper. Teoret. Fiz., 87:9 (2008), 550–555 ; JETP Letters, 87:9 (2008), 464–469 |
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| 32. |
A. B. Petrin, “Axisymmetric instabilities of conducting liquid cylinder in view of the effect of electric field”, TVT, 46:3 (2008), 325–330 ; High Temperature, 46:3 (2008), 291–295 |
| 33. |
A. B. Petrin, “Electric field singularity on the line of wetting of dielectric surface”, TVT, 46:1 (2008), 23–29 ; High Temperature, 46:1 (2008), 19–24 |
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2006 |
| 34. |
V. S. Vorob'ev, S. P. Malyshenko, A. B. Petrin, “The effect of electrically induced convection in dielectric liquids on convective heat transfer”, TVT, 44:6 (2006), 892–902 ; High Temperature, 44:6 (2006), 887–897 |
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| 35. |
A. B. Petrin, “The sensitivity of thermomechanical reading of data”, TVT, 44:4 (2006), 595–603 ; High Temperature, 44:4 (2006), 593–601 |
1
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| 36. |
A. B. Petrin, “An investigation of the heating of electrons in multipolar magnet systems and design of low-pressure electron-cyclotron-resonance microwave-frequency reactors”, TVT, 44:1 (2006), 32–43 ; High Temperature, 44:1 (2006), 29–40 |
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2005 |
| 37. |
A. B. Petrin, “The Heating of Electrons in Magnetic Traps of Low-Pressure Electron-Cyclotron-Resonance Microwave-Frequency Reactors”, TVT, 43:5 (2005), 657–665 ; High Temperature, 43:5 (2005), 653–660 |
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| 38. |
V. S. Vorob'ev, S. P. Malyshenko, A. B. Petrin, “The field-trap effect under conditions of boiling of dielectric liquids in nonuniform electric fields”, TVT, 43:2 (2005), 249–255 ; High Temperature, 43:2 (2005), 240–246 |
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