Оптика мезоразмерных диэлектрических частиц. Oбзор. Часть 1. Оптика
+7 (383) 343-12-55 vestnik@ssga.ru
Ru
En
Ru
En
Авторам публикаций
Вестник СГУГиТАрхив журнала Оптика мезоразмерных диэлектрических частиц. Oбзор. Часть 1. Оптика

Оптика мезоразмерных диэлектрических частиц. Oбзор. Часть 1. Оптика

Оптико-электронные приборы и комплексы
УДК: 535.016:535.361:535.393
DOI: 10.33764/2411-1759-2024-29-1-139-163
И. В. Минин 1, О. В. Минин 1
Год: 2024
Том: 29
№: 1
Страницы: 139 - 163
1 Сибирский государственный университет геосистем и технологий, г. Новосибирск, Российская Федерация

Финансирование: -

Аннотация:

В статье приведен обзор нового научного направления, посвященного оптике диэлектрических мезоразмерных частиц для оптического, сверхвысокочастотного диапазонов и акустики. Материалы с относительно небольшими показателями преломления (n < 2), такие как стекло, кварц, полимеры, некоторые виды керамики и т. д., являются основными материалами для большинства оптических компонентов (линз, оптических волокон и т. д.). В этом обзоре мы представляем некоторые явления и возможные области применения, возникающие в результате от взаимодействия света с частицами с показателем преломления менее 2. Мы также обсудим некоторые другие геометрии частиц (сфероидальные, кубические и т. д.) и различные конфигурации частиц (изолированные или взаимодействующие) и проведем обзор возможных применений таких материалов в связи с улучшением поля зрения, наноскопией с высоким разрешением. Рассмотрены основные области применения таких частиц, включая применение новых фокусирующих устройств – диэлектрических и звукопроводящих частиц, формирующих «фотонные струи» и «фотонные крючки».

Ключевые слова (RU):

диэлектрическая мезоразмерная частица, «фотонная струя», «фотонный крючок», теория Ми, дифракция, интерференция, пространственное разрешение, лазерное структуирование, оптический наноскоп, суперрезонанс, мезоразмерная диэлектрическая антенна, акустическая струя, акустический крюк, мезоразмерная кубоидная

Ключевые слова (EN):

dielectric mesoscale particle, "photon jet", "photon hook", Mi theory, diffraction, interference, spatial resolution, laser structuring, optical nanoscope, superresonance, mesoscale dielectric antenna, acoustic jet, acoustic hook, mesoscale cuboid

Читать статью Скачать JATS XML

Библиографический список:

  1. Luk’yanchuk B. S., Paniagua-Domínguez R., Minin I., Minin O., Wang Z. Refractive index less than two: photonic nanojets yesterday, today and tomorrow // Optical Materials Express. – 2017. – Vol. 7, Issue 6. – P. 1820–1847. – DOI 10.1364/OME.7.001820.
  2. Минин И. В., Минин О. В. Фотонные струи в науке и технике // Вестник СГУГиТ. – 2017. – Т. 22, № 2. – С. 212–234.
  3. Minin I. V., Minin O. V. Diffractive optics and nanophotonics: Resolution below the diffraction limit [Electronic resource]. – Springer, 2016. – Mode of access: http://www.springer.com/us/book/9783319242514#aboutBook.
  4. Томилин М. Г. Глаз и линза через призму тысячелетий // Изв. вузов. Приборостроение. – 2012. – Т. 55, № 3. – С. 70–79.
  5. Кудрявцев П. С. История физики. – М. : Учпедгиз, 1948. – 535 с.
  6. Robert K. G. Temple The Crystal Sun: Rediscovering a Lost Technology of the Ancient World. – Arrow Books Ltd, 2001. – 653 p.
  7. Керпелева С. Ю., Томилин М. Г. Оптические сферы: загадки древних технологий // Оптический журнал. – 1999. – Т. 6, № 1. – С. 88–90.
  8. Rashed R. A Pioneer in Anaclastics: Ibn Sahl on Burning Mirrors and Lenses [Electronic resource] // Isis. – 1990. – Vol. 81, No. 3. – P. 464–491. Retrieved from http://www.jstor.org/stable/233423?seq=1&cid=pdf-reference#references_tab_contents.
  9. Crombie C. Robert Grosseteste and the Origins of Experimental Science. – Oxford: Clarendon Press, 1971. – 369 р.
  10. Li X., Chen Z., Taflove A., Backman V. Optical analysis of nanoparticles via enhanced backscattering facilitated by 3-D photonic nanojets // Optical Express. – 2005. – Vol. 13. – P. 526.
  11. Lu Y. F., Zhang L., Song W. D., Zheng Y. W., Luk’yanchuk B. S. Laser writing of a subwavelength structure on silicon (100) surfaces with particle enhanced optical irradiation // JETP Letter. – 2000. – Vol. 72 (9). – P. 457–459.
  12. Luk’yanchuk B. S., Bekirov A. R., Wang Z. B., Minin I. V., Minin O. V., Fedyanin A. A. Optical Phenomena in Mesoscale Dielectric Spheres and Immersion Lenses Based on Janus Particles: A Review // Physics of Wave Phenomena. – 2022. – Vol. 30, No. 5. – P. 283.
  13. Luk’yanchuk B. S., Bekirov A. R., Wang Z. B., Minin I. V., Minin O. V., Fedyanin A. A.. Optical Phenomena in Dielectric Spheres Several Light Wavelengths in Size: A Review // Physics of Wave Phenomena. – 2022. – Vol. 30, No. 4. – P. 217.
  14. Wang Z. B., Luk'yanchuk B. Super-resolution imaging and microscopy by dielectric particle-lenses, Chapter 15 // Label-Free Super-resolution Microscopy. – Springer, 2019. – P. 371–400.
  15. Wang Z. B., Luk’yanchuk B., Yue L., Yan B., Monks J., Dhama R., Minin O. V., Minin I. V., Huang S. M., Fedyanin A. A. High order Fano resonances and giant magnetic fields in dielectric microspheres // Scientific Reports. – 2019. – Vol. 9. – P. 20293.
  16. Lu Y. F., Zheng Y. W., Song W. D. (2000). Laser induced removal of spherical particles from silicon wafers // Journal of Applied Physics. – 2000. – Vol. 87. – P. 1534–1539.
  17. Leiderer P., Boneberg J., Dobler V., Mosbacher M., Munzer H. J., Chaoui N., Siegel J., Solis J., Afonso C. N., Fourrier T., et al. Laser-induced particle removal from silicon wafers // Proceedings SPIE High-Power Laser Ablation III. – 2000. – P. 249–259. – DOI 10.1117/12.407353.
  18. Luk’yanchuk B. S., Zheng Y. W., Lu Y. F. Laser cleaning of solid surface: optical resonance and nearfield effects // Proceedings SPIE High-Power Laser Ablation III. – 2000. – P. 4012– 4065.
  19. Munzer H. J., Mosbacher M., Bertsch M., Zimmermann J., Leiderer P., Boneberg J. Local field enhancement effects for nanostructuring of surfaces // Journal of Microscopy. – 2001. – Vol. 202. – P. 129–135.
  20. Zheng Y. W., Luk’yanchuk B. S., Lu Y. F., Song W. D., Mai Z. H. Dry laser cleaning of particles from solid substrates: experiments and theory // Journal of Applied Physics. – 2001. – Vol. 90. – P. 2135–2142.
  21. Luk’yanchuk B. S., Mosbacher M., Zheng Y. W., Mu¨nzer H. J., Huang S. M., Bertsch M., Song W. D., Wang Z. B., Lu Y. F., Dubbers O., et al. (2002). Optical resonance and near-field effects in dry laser cleaning // Laser Cleaning / ed. Boris Luk'yanchuk. – New Jersey : World Scientific, 2002. – P. 103–178.
  22. Hong M. H., Wang Z. B., Lukyanchuk B. S., Tan L. S., Chong, T. C. (2006). From transparent particle light enhancement to laser nanoimprinting // Journal of Laser Micro/Nanoengineering. – 2006. – Vol. 1. – P. 61–66.
  23. Huang S. M., Hong M. H., Luk'yanchuk B. S., Zheng Y. W., Song W. D., Lu Y. F. et al. Pulsed laserassisted surface structuring with optical near-field enhanced effects // Journal of Applied Physics. – 2002. – Vol. 92. – P. 2495–2500.
  24. Huang S. M., Sun Z., Luk’yanchuk B. S., Hong M. H., Shi L. P. Nanobump arrays fabricated by laser irradiation of polystyrene particle layers on silicon // Applied Physics Letters. – 2005. – Vol. 86. – P. 161911.
  25. Huang S. M., Wang Z. A., Sun Z., Wang Z. B., Luk'yanchuk B. The Near Field Properties of Colloidal Polystyrene Microspheres on Silicon // Journal of Nanoscience and Nanotechnology. – 2011. – Vol. 11. – P. 10981–10985.
  26. Wang W. J., Lim G. H., Song W. D., Ye K. D., Zhou J., Hong M. H., Liu B. Laser induced nanobump array on magnetic glass disk for low flying height application // Journal of Physics: Conference Series. – 2007. – Vol. 59. – P. 177–180.
  27. Wang Z. B., Guo Wei, Pena A., Whitehead D. J., Luk'yanchuk B. S., Li Lin., Liu Z., Zhou Y., Hong M. H. Laser micro/nano fabrication in glass with tunable-focus particle lens array // Optics Express. – 2008. – Vol. 16(24). – P. 19706.
  28. Khan A., Wang Z., Sheikh M. A., Li L. Laser sub-micron patterning of rough surfaces by micro-particle lens arrays // International Journal of Manufacturing, Materials, and Mechanical Engineering. – 2011. – Vol. 1. – P. 1–9.
  29. Khan A., Wang Z., Sheikh M. A., Whitehead D. J., Li L. Parallel near-field optical micro/nanopatterning on curved surfaces by transported micro-particle lens arrays // Journal of Physics D: Applied Physics. – 2010. – Vol. 43. – P. 30–35.
  30. Liu D. F., Xiang Y. J., Wu X. C., Zhang Z. X., Liu L. F., Song L., Zhao X. W., Luo S. D., Ma W. J., Shen J. et al. Periodic ZnO nanorod arrays defined by polystyrene microsphere self-assembled monolayers // Nano Letters. – 2006. – Vol. 6. – P. 2375–2378.
  31. Okano Y., Umemura S., Enomoto Y., Hayakawa Y., Kumagawa M., Hirata A., Dost, S. Numerical study of Marangoni convection effect on the melting of GaSb/InSb/GaSb // Journal of Crystal Growth. – 2002. – Vol. 235. – P. 135–139.
  32. Khan A., Wang Z., Sheikh M. A., Whitehead D. J., Li L. Laser micro/nano patterning of hydrophobic surface by contact particle lens array // Applied Surface Science. – 2011. – Vol. 258. – P. 774–779.
  33. Li L., Guo W., Wang Z. B., Liu Z., Whitehead D., Luk’yanchuk B. (2009). Large-area laser nanotexturing with user-defined patterns // Journal of Micromechanics and Microengineering. – 2009. – Vol. 19. – P. 054002.
  34. Lin Y., Hong M. H., Chong T. C., Lim C. S., Chen G. X., Tan L. S., Wang Z. B., Shi L. P. Ultrafastlaser-induced parallel phase-change nanolithography // Applied Physics Letters. – 2006. – Vol. 89. – P. 2006–2008.
  35. McLeod E., Arnold C. B. Array-based optical nanolithography using optically trapped microlenses // Optical Express. – 2009. – Vol. 17. – P. 3640–3650.
  36. McLeod E., Arnold C. B. Subwavelength direct-write nanopatterning using optically trapped microspheres // Nature Nanotechnology. – 2008. – Vol. 3. – P. 413–417.
  37. Piglmayer K., Denk R., Bauerle D. Laser-induced surface patterning by means of microspheres // Applied Physics Letters. – 2002. – Vol. 80. – P. 4693–4695.
  38. Yang S., Chen G., Megens M., Ullal C. K., Han, Y. J., Rapaport R., Thomas E. L., Aizenberg J. Functional biomimetic microlens arrays with integrated pores // Advanced Materials. – 2005. – Vol. 17. – P. 435–438.
  39. Kotlyar V. V., Stafeev S. S. Modeling the sharp focus of a radially polarized laser mode using a conical and a binary microaxicon // Journal of the Optical Society of America B. – 2010. – Vol. 27, Issue 10. – P. 1991–1997. – DOI 10.1364/JOSAB.27.001991.
  40. Degtyarev S. A., Porfirev A. P., Khonina S. N. Photonic nanohelix generated by a binary spiral axicon // Applied Optics. – 2016. – Vol. 55. – P. B44–B48.
  41. Минин И. В., Минин О. В. Фотоника изолированных диэлектрических частиц произвольной трехмерной формы – новое направление оптических информационных технологий // Вестник НГУ. Серия: Информационные технологии. – 2014. – Т. 12, вып. 4. – С. 59–70.
  42. Liu C-Y. Photonic jets produced by dielectric micro cuboids // Applied Optics. – 2015. – 2015. – Vol. 54(29). – P. 8694–8699. – DOI 10.1364/AO.54.008694.
  43. Martin J., Proust J., G´erard D., Bijeon J-L., Plain J. Intense Bessel-like beams arising from pyramidshaped microtips // Optical Letter. – 2012. – Vol. 37. – P. 1274-1276.
  44. Mendes M. J., Tobías I., Martí A. and Luque A. Near-field scattering by dielectric spheroidal particles with sizes on the order of the illuminating wavelength // Journal of the Optical Society of America B. – 2010. – Vol. 27, Issue 6. – P. 1221–1231. – DOI 10.1364/JOSAB.27.001221.
  45. Han L., Han Y., Gouesbet G., Wang J., Gr´ehan G. Photonic jet generated by spheroidal particle with Gaussian-beam illumination // Journal of the Optical Society of America B. – 2014. –Vol. 31(7). – P. 1476–1483. – DOI 10.1364/JOSAB.31.001476.
  46. Han L., Han Y., Wang J., Cui Z. Internal and near-surface electromagnetic fields for a dielectric spheroid illuminated by a zero-order Bessel beam // Journal of the Optical Society of America A. – 2014. – Vol. 31, Issue 9. – P. 1946–1955. – DOI 10.1364/JOSAA.31.001946.
  47. Yue L., Minin O. V., Wang Z., Monks J. N., Shalin A. S. and Minin I. V. Photonic hook: a new curved light beam // Optical Letter. – 2018. – Vol. 43(4). – P. 771–774.
  48. Hengyu Z., Zaichun C., Chong C. T. and Minghui H. Photonic jet with ultralong working distance by hemispheric shell // Optical Express. – 2015. – Vol. 23(5). – P. 6626–33. – DOI 10.1364/OE.23.006626.
  49. Liu C-Y., Chen C-J. Characterization of photonic nanojets in dielectric microdisks // Physica E Lowdimensional Systems and Nanostructures. – 2015. – Vol. 73. – P. 226-234. – DOI 10.1016/j.physe.2015. 06.005.
  50. McCloskey D., Wang J. J. and Donegan J. F. Low divergence photonic nanojets from Si3N4 microdisks // Optics Express. – 2012. – Vol. 20(1). – P. 128-40. – DOI 10.1364/OE.20.000128.
  51. McCloskey D., Ballantine K. E., Eastham P. R., Donegan J. F. Photonic nanojets in Fresnel zone scattering from non-spherical dielectric particles // Optics Express. – 2015. – Vol. 23(20). – P. 26326. – DOI 10.1364/OE.23.026326.
  52. Minin I. V., Minin O. V., Geints Y. E. Localized EM and photonic jets from non-spherical and nonsymmetrical dielectric mesoscale objects: Brief review // Annalen der Physik. – 2015. – Vol. 527(7). – DOI 10.1002/andp.201500132
  53. Minin I. V., Minin O. V. Photonic jets formation by non spherical axially and spatially asymmetric 3D dielectric particles // Diffractive Optics and Nanophotonics. – Berlin: Springer, 2016. – P. 31–54.
  54. Liu C-Y., Minin O. V., Minin I. V. First experimental observation of array of photonic jets from sawtooth phase diffraction grating // Europhysics Letters. – 2018. – Vol. 123. – P. 54003.
  55. Minin I. V., Minin O. V., Glinskiy I. A., Khabibullin R. A., Malureanu R., Lavrinenko A. V., Yakubovsky D. I., Arsenin A. V., Volkov V. S., Ponomarev D. S. Plasmonic nanojet: an experimental demonstration // Optics Letters. – 2020. – Vol. 45. – P. 3244–3247. – DOI 10.1364/OL.391861.
  56. Pacheco-Peña V., Minin I. V., Minin O. V., & Beruete M. Comprehensive analysis of photonic nanojets in 3D dielectric cuboids excited by surface plasmons // Annalen der Physik. – 2016. – Vol. 528(9-10). – P. 684–692. – DOI 10.1002/andp.201600098/.
  57. Pacheco-Peña V., Minin I. V., Minin O. V., Beruete M. Increasing Surface Plasmons Propagation via Photonic Nanojets with Periodically Spaced 3D Dielectric Cuboids // Photonics 2016. – Vol. 3(10). – DOI 10.3390/www.mdpi.com/journal/photonics.
  58. Luk’yanchuk B. S. Laser Cleaning. – World Scientific, 2002. – 466 p.
  59. Beklemyshev V. I., Makarov V. V., Makhonin I. I., Petrov Yu. N., Prokhorov A. M., and Pustovoy V. I., Photo desorption of metal ions in a semiconductor-water system // JETP Letters. – 1987. – Vol. 46(7). – P. 347–350.
  60. Zapka W., Asch K., Meissner K. Removal of particles from solid-state surfaces by laser bombardement // European Patent EP 0297506 В1 Publication Date: 05/20/1998.
  61. Wang Z. B., Guo W., Luk'yanchuk B. S., Pena A., Li L., Liu Z. Laser ablation on nanoscales // Proceedings SPIE. High-Power Laser Ablation VII – 2008. – Vol. 7005. – DOI 10.1117/12.780065.
  62. Fardel R., McLeod E., Tsai Y.-C., Arnold C. B. Nanoscale ablation through optically trapped microspheres // Applied Physics A. – 2010. – Vol. 101. – P. 41–46.
  63. Münzer H.-J., Mosbacher M., Bertsch M., Dubbers O., Burmeister F., Pack A., Wannemacher R., Runge B.-U., Bäuerle D., Boneberg J., Leiderer P. Optical near-field effects in surface nanostructuring and laser cleaning // Proceedings SPIE. – 2002. – Vol. 4426. – DOI 10.1117/12.456827.
  64. Mosbacher M., Munzer H. J., Zimmermann J., Solis J., Boneberg J., Leiderer P. Optical field enhancement effects in laser-assisted particle removal // Applied Physics a-Materials Science & Processing. – 2001. – Vol. 72. – P. 41–44.
  65. Lu Y., Theppakuttai S., Chen S. C. Marangoni effect in nanosphere-enhanced laser nanopatterning of silicon // Applied Physics Letters. – 2003. – Vol. 82. – P. 4143–4145.
  66. Theppakuttai S., Chen S. Nanoscale surface modification of glass using a 1064 nm pulsed laser // Applied Physics Letters. – 2003. – Vol. 83. – P. 758–760.
  67. Chen Z. G., Taflove A., Backman V. Photonic nanojet enhancement of backscattering of light by nanoparticles: a potential novel visible-light ultramicroscopy technique // Optics Express. – 2004. – Vol. 12. – P. 1214–1220.
  68. Kim J., Cho K., Kim I., Kim W. M., Lee T. S., Lee K.-S. Fabrication of plasmonic nanodiscs by photonic nanojet lithography // Applied Physics Express. – 2012. – Vol. 5. – P. 025201.
  69. Zhang X. A., Chen I.-T., Chang C. H. Recent progress in near-field nanolithography using light interactions with colloidal particles: from nanospheres to three-dimensional nanostructures // Nanotechnology. – 2019. – Vol. 30. – P. 352002.
  70. Chen X., Wu T., Gong Z., Li Y., Zhang Y., Li B. Subwavelength imaging and detection using adjustable and movable droplet microlenses // Photonics Research. – 2020. – Vol. 8. – P. 225–234.
  71. Astratov V. N., Darafsheh A., Kerr M. D., Allen K. W., Fried N. M., Antoszyk A. N., Ying H. S. Photonic nanojets for laser surgery // SPIE Newsroom. – 2010. – Vol. 12. – P. 32–34.
  72. Yan B., Yue L., Monks J. N., Yang X., Xiong D., Jiang C., Wang Z. B. Superlensing Plano-ConvexMicrosphere (PCM) lens for direct laser nano marking and beyond // Optics Letters. – 2020. – Vol. 45. – P. 1168-1171.
  73. Wang F., Liu L., Yu P., Liu Z., Yu H., Wang Y., Li W. J. Three-Dimensional Super- Resolution Morphology by Near-Field Assisted White-Light Interferometry // Scientific Reports. – 2016. – Vol. 6. – P. 24703.
  74. Qian L., Jianqi S. Effect of Resonant Scattering on Photonic Jet of a Microsphere // Acta Photonica Sinica. – 2021. – Vol. 50. – P. 729002.
  75. Минин И. В., Минин О. В. Квазиоптика: современные тенденции развития – Новосибирск : СГУГиТ, 2015. – 163 с.
  76. Минин И. В., Минин О. В. Сверхразрешение в акустических фокусирующих устройствах // Вестник СГУГиТ. – 2018. – Т. 23, № 2. – С. 231–244.
  77. Heifetz A., Kong S.-Ch., Sahakian A. V., Taflove A., Backman V. Photonic Nanojets // Journal of Computational and Theoretical Nanoscience. – 2009. – Vol. 6. – P. 1979–1992.
  78. Lecler S., Takakura Y., Meyrueis P. Properties of a three-dimensional photonic jet // Optics Letters. – 2005. – Vol. 30. – P. 2641–2643.
  79. Wu W., Katsnelson A., Memis O. G., Mohseni H. A deep sub-wavelength process for the formation of highly uniform arrays of nanoholes and nanopillars // Nanotechnology. – 2007. – Vol. 18. – P. 485302.
  80. Fukuda N., Kunishio K., Nakayama S. Dry-Etching System with Q-switched DPSS Laser for Flat Panel Displays // Journal of Laser Micro Nanoengineering. – 2007. – Vol. 2. – P. 241–246.
  81. Geints Y. E., Minin I. V., Panina E. K., Zemlyanov A. A., Minin O. V. Comparison of photonic nanojets key parameters produced by nonspherical microparticles // Optical and Quantum Electronics. – 2017. – Vol. 49. – P. 118. – DOI 10.1007/s11082-017-0958-y.
  82. Минин И. В., Минин О. В., Карпик А. П. Фотонные наноструи, тераструи и акустоструи в науке и технике. – Новосибирск : СГУГиТ, 2021. – 168 с.
  83. Li H., Song W., Zhao Y., Cao Q., Wen A., Optical Trapping, Sensing and Imaging by Photonic Nanojets // Photonic. – 2021. – Vol. 8. – P. 434. – DOI 10.3390/photonics8100434.
  84. Darafsheh A. Photonic nanojets and their applications // Journal of Physics: Photonics. – 2021. – Vol. 3. – P. 022001.
  85. Minin O. V., Minin I. V. Optical Phenomena in Mesoscale Dielectric Particles // Photonics. – 2021. – Vol. 8. – P. 591.
  86. Chen L., Zhou Y., Wu M.-X., Hong M.-H. Remote-mode microsphere nano-imaging: new boundaries for optical microscopes // Opto-Electronic Advances. – 2018. – Vol. 1. – P. 170001.
  87. Chen Z., Taflove A., Backman V. Equivalent volume-averaged light scattering behavior of randomly inhomogeneous dielectric spheres in the resonant range // Optical Express. – 2004. – Vol. 12. – P. 1214.
  88. Abbe E. Beitra¨ge zur Theorie des Mikroskops und der mikroskopischen Wahrnehmung // Arch. Mikrosk. Anat. – 1873. – Vol. 9. – P. 413–418.
  89. Rayleigh L. Investigations in optics, with special reference to the spectroscope. London, Edinburgh, Dublin // Philosophical Magazine. – 1879. – Vol. 8. – P. 477–486.
  90. Chen L., Zhou Y., Zhou R., Hong M. Microsphere – Toward Future of Optical Microscopes // iScience. – 2020. – Vol. 23. – P. 101211.
  91. Wang, Z., Guo, W., Li, L., Luk’yanchuk, B., Khan, A., Liu, Z., Chen, Z., Hong, M. Optical virtual imaging at 50 nm lateral resolution with a white-light nanoscope // Nature Communications. – 2011. – Vol. 2. – P. 216–218.
  92. Lu Y. F., Zhang L., Song W. D., Zheng Y. W., Luk’yanchuk B. S. Laser writing of a subwavelength structure on silicon (100) surfaces with particle-enhanced optical irradiation // Journal of Experimental and Theoretical Physics. – 2000. – Vol. 72. – P. 457–459.
  93. Wang Z. B. et al. Optical virtual imaging at 50 nm lateral resolution with a whitelight nanoscope // Nature Communications. – 2011. – Vol. 2(1). – P. 218. – DOI 10.1038/ncomms1211.
  94. Krivitsky L. A., Wang J. J., Wang Z., Luk’yanchuk B. Locomotion of microspheres for super-resolution imaging // Scientific Report. – 2013. – Vol. 3(1). – P. 3501. – DOI 10.1038/srep03501.
  95. Yan Y., Li L., Feng C., Guo W., Lee S., Hong M. H. Microsphere coupled scanning laser confocal nanoscope for sub-diffraction limited imaging at 25 nm lateral resolution in the visible spectrum // ACS Nano. – 2014. – Vol. 8. – P. 1809–1816.
  96. Monks J. N., Yan B., Hawkins N., Vollrath F., Wang Z. B. Spider silk: mother nature’s bio-superlens // Nano Letters. – 2016. – Vol. 16. – P. 5842–5845.
  97. Wang F., Liu L., Yu H., Wen Y., Yu P., Liu Zh., Wang Y., Li W. J. Scanning superlens microscopy for non-invasive large field-of-view visible light nanoscale imaging // Nature Communications. – 2016. – Vol. 7. – P. 13748.
  98. Guo M., Ye Y.-H., Hou J., Du B. Size-dependent optical imaging properties of high-index immersed microsphere lens // Applied Physics B. – 2016. – Vol. 122(3). – DOI 10.1007/s00340-016-6335-x.
  99. Lee S., Li L., Wang Z., Guo W., Yan Y., Wang T. Immersed transparent microsphere magnifying subdiffraction-limited objects // Applied Optics. – 2013. – Vol. 52. – P. 7265–7270.
  100. Hao X., Kuang C., Liu X., Zhang H., Li Y. Microsphere based microscope with optical super-resolution capability // Applied Physics Letters. – 2011. – Vol. 99. – P. 203102.
  101. Wang F., Yang S., Ma H., Shen P., Wei N., Wang M., Xia Y., Deng Y., Ye Y.-H. Microsphereassisted super-resolution imaging with enlarged numerical aperture by semi-immersion // Applied Physics Letters. – 2018. – Vol. 112. – P. 023101.
  102. Hoff J. C., Akin E. W. Microbial resistance to disinfectants: Mechanisms and significance // Environmental Health Perspectives. – 1986. – Vol. 69. – P. 7–13.
  103. Lee S., Li L., Ben-Aryeh Y., Wang Z., Guo W. Overcoming the diffraction limit induced by microsphere optical nanoscopy // Journal of Optics. – 2013. – Vol. 15. – P. 125710.
  104. Chen, L., Zheng, X., Du, Z., Jia, B., Gu, M., Hong, M. A frozen matrix hybrid optical nonlinear system enhanced by a particle lens // Nanoscale. – 2015. – Vol. 7. – P. 14982–14988.
  105. Chen L., Yin Y., Li Y., Hong M. Multifunctional inverse sensing by spatial distribution characterization of scattering photons // Opto-Electronic Advances. – 2019. – Vol. 2. – P. 190019.
  106. Gao M., Ng S. W. L., Chen L., Hong M., Ho G. W. Self-regulating reversible photocatalytic-driven chromism of a cavity enhanced optical field TiO2/CuO nanocomposite // Journal of Materials Chemistry A. – 2017. – Vol. 5. – P. 10909– 10916.
  107. Jin Y. J., Chen L. W., Wu M. X., Lu X. Z., Zhou R., Hong M. H. Enhanced saturable absorption of the graphene oxide film via photonic nanojets // Optical Materials Express. – 2016. – Vol. 6. – P. 1114– 1121.
  108. Soh J. H., Wu M., Gu G., Chen L., Hong M. Temperature-controlled photonic nanojet via VO2 coating // Applied Optics. – 2016. – Vol. 55. – P. 3751–3756.
  109. Jin B., Bidney G. W., Anisimov I., Limberopoulos N. I., Allen K. W, Maslov A. V., Astratov V. N. Label-free cellphone microscopy with submicron resolution through high-index contact ball lens for in vivo melanoma diagnostics and other applications // Proceedings SPIE Label-free Biomedical Imaging and Sensing (LBIS). – 2022. – Vol. 11972. – DOI 10.1117/12.2609911.
  110. Wang T., Kuang C., Hao X., Liu X. Subwavelength focusing by a microsphere array // Journal of Optics. – 2011. – Vol. 13. – P. 1–5. – DOI 10.1088/2040-8978/13/3/035702.
  111. Минин И. В., Минин О. В. Проблемы метрологии терагерцового излучения в медицине // Вестник СГУГиТ. – 2021. – Т. 26, № 3. – С. 162–180.
  112. Yanina I. Yu., Dyachenko P. A., Abdurashitov A. S., Shalin A. S., Minin I. V., Minin O. V., Bulygin A. D., Vrazhnov D. A., Kistenev Y. V., Tuchin V. V. Light distribution in fat cell layers at physiological temperatures // Scientifc Reports. – 2023. – Vol. 13. – P. 1073. – DOI 10.1038/s41598-022-25012-9.
  113. Minin O. V., Minin I. V., Cao Y. Time domain self-bending photonic hook beam based on freezing water droplet // Scientific Reports. – 2023. – Vol. 13. – Article number 7732.
  114. Minin O. V., Zhou S., Liu C.-Y., Antonicole J., Kong N., Minin I. V. Magnetic Concentric Hot-Circle Generation at Optical Frequencies in All-Dielectric Mesoscale Janus Particles // Nanomaterial. – 2022. – Vol. 12. – P. 3428. – DOI 10.3390/nano12193428.
  115. Минин И. В., Жоу С., Минин О. В. Эффект суперрезонанса в мезоразмерной сфере с малым коэффициентом преломления // Оптика атмосферы и океана. – 2022. – Vol. 35(9). – P. 697–703. – DOI 10.15372/AOO20220901.
  116. Yue L., Yan B., Monks J. N., Dhama R., Jiang C., Minin O. V., Minin I. V., Wang Z. Full threedimensional Poynting vector analysis of great field-intensity enhancement in a specifically sized sphericalparticle // Scienyific Report. – 2019. – Vol. 9. – P. 20224.
  117. Минин И. В., Минин О. В. Оптический суперрезонанс в мезоразмерных диэлектрических сферах // Фотоника. – 2022. – Т. 16, № 4. – С. 306–317.
  118. Fano U. Effects of configuration interaction on intensities and phase shift // Physical Review. – 1961. – Vol. 124(6). – P. 1866.
  119. Минин И. В., Минин О. В., Джоу С. Фано резонанс высокого порядка в диэлектрической мезоразмерной сфере из материала с низким показателем преломления // Письма в ЖЭТФ. – 2022. – Т. 116, № 3. – С. 146–150.
  120. Минин И. В., Минин О. В. Особенности генерации экстремальных электромагнитных полей в диэлектрической мезоразмерной сфере с учетом окружающей среды // Письма в ЖЭТФ. – 2022. – Т. 48, № 18. – С. 41–44.
  121. Liu Ch.-Y., Minin O. V., Minin I. V. Periodical focusing mode achieved through a chain of mesoscale dielectric particles with a refractive index near unity // Optics Communications. – 2019. – Vol. 434. – P. 110–117.
  122. Geints Y., Minin I. V., Minin O. V. Whispering-gallery modes promote enhanced optical backflow in a perforated dielectric microsphere // Optics Letters. – 2022. – Vol. 47, Issue 7. – P. 1786–1789. – DOI 10.1364/OL.452683.
  123. Geints Y. E., Minin I. V., Minin O. V. Simulation of enhanced optical trapping in a perforated dielectric microsphere amplified by resonant energy backflow // Optics Communications. – 2022. – Vol. 524. – P. 128779.

Образец цитирования:

Минин И. В., Минин О. В. Оптика мезоразмерных диэлектрических частиц. Oбзор. Часть 1. Оптика // Вестник СГУГиТ. – 2024. – Т. 29, № 1. – С. 139–163. – DOI 10.33764/2411-1759-2024-29-1-139-163