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Byers, J. C., Heiser, T., Skorobogatiy, M. A., & Semenikhin, O. A. (2016). Effect of aging and PCBM content on bulk heterojunction organic solar cells studied by intensity modulated photocurrent spectroscopy. ACS Applied Materials & Interfaces, 8(42), 28789-28799. Lien externe
Berzowska, J., & Skorobogatiy, M. A. (janvier 2010). Karma Chameleon: Bragg fiber Jacquard-woven photonic textiles [Communication écrite]. 4th International Conference on Tangible, Embedded, and Embodied Interaction, TEI'10. Lien externe
Berzowska, J., & Skorobogatiy, M. A. (août 2009). Karma Chameleon: Jacquard-woven photonic fiber display [Communication écrite]. 36th International Conference and Exhibition on Computer Graphics and Interactive Techniques (SIGGRAPH 2009), New Orleans, Louisiana. Lien externe
Cao, Y., Nallappan, K., Xu, G., & Skorobogatiy, M. A. (2023). Resonant gas sensing in the terahertz spectral range using two-wire phase-shifted waveguide Bragg gratings. Sensors, 23(20), 8527 (10 pages). Disponible
Cao, Y., Nallappan, K., Xu, G., & Skorobogatiy, M. A. (novembre 2023). Phase-shifted two-wire waveguide Bragg gratings for high sensitivity gas detection in the Terahertz range [Communication écrite]. IEEE Photonics Conference (IPC 2023), Orlando, FL, USA (2 pages). Lien externe
Cao, Y., Nallappan, K., Xu, G., & Skorobogatiy, M. A. (2022). Add drop multiplexers for terahertz communications using two-wire waveguide-based plasmonic circuits. Nature Communications, 13(1), 4090 (12 pages). Lien externe
Chernomyrdin, N. V., Lavrukhin, D. V., Ulitko, V. E., Galiev, R. R., Gavdush, A. A., Anzin, V. B., Perov, A. N., Katyba, G. M., Tuchin, V. V., Skorobogatiy, M. A., Reshetov, I. V., Ponomarev, D. S., & Zaytsev, K. I. (2022). Continuously tunable middle-IR bandpass filters based on gradient metal-hole arrays for multispectral sensing and thermography. Journal of Applied Physics, 131(12), 10 pages. Lien externe
Chapdelaine, Q., Nallappan, K., Cao, Y., Guerboukha, H., Chernomyrdin, N., Zaytsev, K., & Skorobogatiy, M. A. (2022). Fabrication and characterization of a composite TiO₂-polypropylene high-refractive-index solid immersion lens for super-resolution THz imaging. Optical Materials Express, 12(8), 3015-3031. Lien externe
Chapdelaine, Q., Nallappan, K., Cao, Y., Xu, G., Chernomyrdin, N., Guerboukha, H., Zaitsev, K., & Skorobogatiy, M. A. (juillet 2022). Fabrication and characterization of high permittivity solid immersion lenses for terahertz microscopy applications [Communication écrite]. IEEE Photonics Society Summer Topicals Meeting Series (SUM 2022), Cabo San Lucas, Mexico (2 pages). Lien externe
Chernomyrdin, N. V., Skorobogatiy, M. A., Ponomarev, D. S., Bukin, V. V., Tuchin, V. V., & Zaytsev, K. I. (2022). Terahertz solid immersion microscopy: Recent achievements and challenges. Applied Physics Letters, 120(11), 11 pages. Lien externe
Cao, Y., Nallappan, K., Guerboukha, H., Xu, G., & Skorobogatiy, M. A. (juillet 2021). Additive manufacturing of reconfigurable two-wire plasmonic circuits for terahertz communications [Communication écrite]. IEEE Photonics Society Summer Topicals Meeting Series (SUM 2021), Cabo San Lucas, Mexico (2 pages). Lien externe
Cao, Y., Nallappan, K., Guerboukha, H., Xu, G., & Skorobogatiy, M. A. (octobre 2021). Additive manufacturing of reconfigurable two-wire plasmonic circuits for terahertz communications [Communication écrite]. Annual Conference of the IEEE-Photonics-Society (IPC 2022). Lien externe
Cherkasova, O. P., Serdyukov, D. S., Nemova, E. F., Ratushnyak, A. S., Kucheryavenko, A. S., Dolganova, I. N., Xu, G., Skorobogatiy, M. A., Reshetov, I. V., Timashev, P. S., Spektor, I. E., Zaytsev, K. I., & Tuchin, V. V. (2021). Cellular effects of terahertz waves. Journal of Biomedical Optics, 26(9), 53 pages. Lien externe
Cao, Y., Nallappan, K., Guerboukha, H., Xu, G., & Skorobogatiy, M. A. (mai 2021). Modular 3D-Printed Plasmonic Circuits for Signal Processing in THz Communications [Communication écrite]. Conference on Lasers and Electro-Optics (CLEO 2021), San José, CA, USA (2 pages). Lien externe
Chernomyrdin, N. V., Skorobogatiy, M. A., Gavdush, A. A., Musina, G. R., Katyba, G. M., Komandin, G. A., Khorokhorov, A. M., Spektor, I. E., Tuchin, V. V., & Zaytsev, K. I. (2021). Quantitative super-resolution solid immersion microscopy via refractive index profile reconstruction. Optica, 8(11), 1471-1480. Lien externe
Cao, Y., Nallappan, K., Guerboukha, H., Xu, G., & Skorobogatiy, M. A. (2020). Additive manufacturing of highly reconfigurable plasmonic circuits for terahertz communications. Optica, 7(9), 1112-1125. Lien externe
Chernomyrdin, N. V., Kucheryavenko, A. S., Kolontaeva, G. S., Katyba, G. M., Dolganova, I. N., Karalkin, P. A., Ponomarev, D. S., Kurlov, V. N., Reshetov, I. V., Tuchin, V. V., Skorobogatiy, M. A., & Zaytsev, K. I. (février 2020). Principles of solid immersion imaging and its application to super resolution microscopy of soft biological tissues in the terahertz spectral range [Communication écrite]. SPIE Medical Imaging, Houston, Texas, USA. Lien externe
Cao, Y., Nallappan, K., Guerboukha, H., Gervais, T., & Skorobogatiy, M. A. (2019). Additive manufacturing of resonant fluidic sensors based on photonic bandgap waveguides for terahertz applications. Optics Express, 27(20), 27663-27681. Lien externe
Cao, Y., Nallappan, K., Guerboukha, H., Gervais, T., & Skorobogatiy, M. A. (septembre 2019). Photonic Bandgap Bragg Waveguide-based Terahertz Microfluidic Sensor [Communication écrite]. 44th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2019), Paris, France (2 pages). Lien externe
Cao, Y., Nallappan, K., Guerboukha, H., Gervais, T., & Skorobogatiy, M. A. (mars 2019). Photonic Bandgap Bragg Waveguide-based Terahertz Microfluidic Sensor [Résumé]. 8th International Conference on Optical Terahertz Science and Technology (OTST 2019), Santa Fe, NM, USA. Lien externe
Chernomyrdin, N. V., Kucheryavenko, A. S., Kolontaeva, G. S., Katyba, G. M., Dolganova, I. N., Karalkin, P. A., Ponomarev, D. S., Kurlov, V. N., Reshetov, I. V., Skorobogatiy, M. A., Tuchin, V. V., & Zaytsev, K. I. (2018). Reflection-mode continuous-wave 0.15 lambda-resolution terahertz solid immersion microscopy of soft biological tissues. Applied Physics Letters, 113(11), 111102 (4 pages). Lien externe
Chernomyrdin, N. V., Schadko, A. O., Lebedev, S. P., Tolstoguzov, V. L., Kurlov, V. N., Reshetov, I. V., Spektor, I. E., Skorobogatiy, M. A., Yurchenko, S. O., & Zaytsev, K. I. (2017). Solid immersion terahertz imaging with sub-wavelength resolution. Applied Physics Letters, 110(22), 4 pages. Lien externe
Deck-Leger, Z.-L., Chamanara, N., Skorobogatiy, M. A., Silveirinha, M. G., & Caloz, C. (2019). Uniform-velocity spacetime crystals. Advanced Photonics, 1(5), 26 pages. Lien externe
Deck-Leger, Z. L., Chamanara, N., Skorobogatiy, M. A., & Caloz, C. (août 2017). Space-time (ST) reflection focusing in dispersion-engineered medium [Communication écrite]. 32nd General Assembly and Scientific Symposium of the International Union of Radio Science (URSI GASS 2017), Montréal, Québec (3 pages). Lien externe
Deck-Léger, Z.-L., Skorobogatiy, M. A., & Caloz, C. (juin 2016). Diagrammatic explanation of the reverse doppler effect in space-time modulated photonic crystals [Communication écrite]. IEEE International Symposium on Antennas and Propagation (APSURSI 2016), Fajarjo, Puerto Rico. Lien externe
Dupuis, A., Stoeffler, K., Ung, B., Dubois, C., & Skorobogatiy, M. A. (2011). Transmission measurements of hollow-core THz Bragg fibers. Journal of the Optical Society of America B: Optical Physics, 28(4), 896-907. Lien externe
Dupuis, A., Mazhorova, A., Desevedavy, F., & Skorobogatiy, M. A. (mai 2010). Loss and spectral measurements of porous and non-porous subwavelength THz fibers [Communication écrite]. Conference on Lasers and Electro-Optics (CLEO), San Jose, California. Lien externe
Dupuis, A., Mazhorova, A., Desevedavy, F., & Skorobogatiy, M. A. (septembre 2010). Propagation loss measurements of porous THz subwavelength fibers [Communication écrite]. 35th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2010), Rome. Lien externe
Dupuis, A., Mazhorova, A., Desevedavy, F., Roze, M., & Skorobogatiy, M. A. (2010). Spectral characterization of porous dielectric subwavelength THz fibers fabricated using a microstructured molding technique. Optics Express, 18(13), 13813-13828. Lien externe
Dupuis, A., Hassani, A., & Skorobogatiy, M. A. (juin 2009). Design and fabrication of subwavelength THz fibers with multiple holes [Communication écrite]. Conference on Lasers and Electro-Optics and 2009 Conference on Quantum Electronics and Laser Science Conference, Baltimore, MD, United states. Lien externe
Dupuis, A., Allard, J.-F., Morris, D., Stoeffler, K., Dubois, C., & Skorobogatiy, M. A. (2009). Fabrication and THz loss measurements of porous subwavelength fibers using a directional coupler method. Optics Express, 17(10), 8012-8028. Lien externe
Dupuis, A., Guo, N., Gauvreau, B., Hassani, A., Pone, E., Boismenu, F., & Skorobogatiy, M. A. (mai 2008). "Colorful" solid-core Bragg fibers guiding in the visible [Communication écrite]. Conference on Lasers and Electro-Optics and Conference on Quantum Electronics and Laser Science (CLEO-QELS 2008), San Jose, CA, United States. Lien externe
Dupuis, A., Guo, N., Gauvreau, B., Hassani, A., Pone, E., Boismenu, F., & Skorobogatiy, M. A. (février 2008). All-fiber spectral filtering with solid core photonic band gap Bragg fibers [Communication écrite]. OFC/NFOEC 2008 Optical Fiber Communication Conference/National Fiber Optic Engineers Conference. Lien externe
Dupuis, A., Hassani, A., & Skorobogatiy, M. A. (janvier 2008). Designs of porous polymer THz fibers [Communication écrite]. Ultrafast Phenomena in Semiconductors and Nanostructure Materials XII, San Jose, California. Lien externe
Dubois, C., Skorobogatiy, M. A., Ajji, A., & Stoeffler, K. (octobre 2008). Fabrication of 1D photonic crystals based on hollow/solid-core all-polymer optic fibers [Communication écrite]. 2008 Fiber Society Fall Meeting and Technical Conference, Boucherville, Québec, Canada. Non disponible
Dupuis, A., Guo, N., Gao, Y., Skorobogata, O., Gauvreau, B., Dubois, C., & Skorobogatiy, M. A. (2008). Fabrication strategies and potential applications of the “green” microstructured optical fibers. Journal of Biomedical Optics, 13(5), 054003-054003. Lien externe
Dupuis, A., Guo, N., Gao, Y., Gauvreau, B., Dubois, C., & Skorobogatiy, M. A. (mai 2008). Prospects for "green" microstructured optical fibers [Communication écrite]. Conference on Lasers and Electro-Optics and Conference on Quantum Electronics and Laser Science (CLEO-QELS 2008), San Jose, CA, United States. Lien externe
Dupuis, A., Guo, N., Gauvreau, B., Hassani, A., Pone, E., Boismenu, F., & Skorobogatiy, M. A. (2007). Guiding in the Visible With "Colorful" Solid-Core Bragg Fibers. Optics Letters, 32(19), 2882-2884. Lien externe
Dupuis, A., Guo, N., Gao, Y., Godbout, N., Lacroix, S., Dubois, C., & Skorobogatiy, M. A. (2007). Prospective for Biodegradable Microstructured Optical Fibers. Optics Letters, 32(2), 109-111. Lien externe
Dupuis, A., Gao, Y., Guo, N., Pone, E., Godbout, N., Lacroix, S., Dubois, C., & Skorobogatiy, M. A. (septembre 2006). Biodegradable, double-core, porous optical fiber [Communication écrite]. 15th International Conference on Plastic Optical Fibers, Seoul, Korea. Non disponible
Dupuis, A., Gao, Y., Guo, N., Pone, E., Godbout, N., Lacroix, S., Dubois, C., & Skorobogatiy, M. A. (mai 2006). Biodegradable, double-core, porous optical fiber [Communication écrite]. CLEO 2006, Long Beach, CA, USA. Lien externe
Dupuis, A., Gao, Y., Guo, N., Pone, E., Godbout, N., Lacroix, S., Dubois, C., & Skorobogatiy, M. A. (octobre 2006). Biodegradable, double-core, porous optical fiber for sensing applications [Communication écrite]. 18th International Conference on Optical Fiber Sensors, Cancun, Mexico. Lien externe
Feng Gu, J., Gorgutsa, S., & Skorobogatiy, M. A. (2010). Soft capacitor fibers for electronic textiles. Applied Physics Letters, 97(13), 133305-133305. Lien externe
Feng Gu, J., Gorgutsa, S., & Skorobogatiy, M. A. (2010). Soft capacitor fibers using conductive polymers for electronic textiles. Smart Materials and Structures, 19(11), 115006-115006. Lien externe
Florous, N. I., Saitoh, K., Koshiba, M., & Skorobogatiy, M. A. (2006). Low-temperature-sensitivity heterostructure photonic-crystal wavelength-selective filter based on ultralow-refractive-index metamaterials. Applied Physics Letters, 88(12), 121107-121107. Lien externe
Florous, N. J., Saitoh, K., Murao, T., Koshiba, M., & Skorobogatiy, M. A. (2006). Non -proximity resonant tunneling in multi-core photonic band gap fibers: An efficient mechanism for engineering highly-selective ultra-narrow band pass splitters. Optics Express, 14, 4861-4872. Lien externe
Guerboukha, H., Skorobogatiy, M. A., & Mittleman, D. M. (juillet 2022). Localization in wireless terahertz communications: An imaging problem and a spectral encoding solution [Communication écrite]. IEEE Photonics Society Summer Topicals Meeting Series (SUM 2022), Cabo San Lucas, Mexico (2 pages). Lien externe
Gavdush, A. A., Chernomyrdin, N. V., Lavrukhin, D. V., Cao, Y., Komandin, G. A., Spektor, I. E., Perov, A. N., Dolganova, I. N., Katyba, G. M., Kurlov, V. N., Ponomarev, D. S., Skorobogatiy, M. A., Reshetov, I. V., & Zaytsev, K. I. (2020). Proof of concept for continuously-tunable terahertz bandpass filter based on a gradient metal-hole array. Optics Express, 28(18), 26228-26238. Lien externe
Guerboukha, H., Cao, Y., Nallappan, K., & Skorobogatiy, M. A. (2020). Super-Resolution Orthogonal Deterministic Imaging Technique for Terahertz Subwavelength Microscopy. ACS Photonics, 7(7), 1866-1875. Lien externe
Guerbouka, H., Cao, Y., Nallannan, K., & Skorobogatiy, M. A. (novembre 2020). Super-resolution Terahertz Microscopy with Deterministic Artificial Fluorophores [Communication écrite]. 45th International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2020), Buffalo, NY, USA (2 pages). Lien externe
Guerboukha, H., Nallappan, K., & Skorobogatiy, M. A. (mai 2019). Imagerie térahertz par encodage spectral [Résumé]. 87e Congrès de l'Association francophone pour le savoir (ACFAS), Gatineau, Québec, Canada. Lien externe
Guerboukha, H., Nallappan, K., Cao, Y., & Skorobogatiy, M. A. (janvier 2019). Low-loss planar components for THz wireless communications [Communication écrite]. IEEE Radio and Wireless Symposium (RWS 2019), Orlando, Florida (4 pages). Lien externe
Guerboukha, H., Nallappan, K., Cao, Y., & Skorobogatiy, M. A. (mars 2019). Low-Loss Planar Components for THz Wireless Communications [Communication écrite]. International Workshop on Antenna Technology (iWAT 2019), Miami, FL, United states. Lien externe
Guerboukha, H., Nallappan, K., Cao, Y., & Skorobogatiy, M. A. (janvier 2019). Low-loss planar components for THz wireless communications [Communication écrite]. IEEE Radio Wireless Week 2019, Orlando, Florida, USA. Lien externe
Guerboukha, H., Nallappan, K., Cao, Y., Seghilani, M., Azana, J., & Skorobogatiy, M. A. (septembre 2019). Low-loss planar porous components for terahertz beamforming [Communication écrite]. 44th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2019), Paris, France (2 pages). Lien externe
Guerboukha, H., Nallappan, K., Cao, Y., & Skorobogatiy, M. A. (2019). Low-loss porous optical components. Optics & Photonics News, December, 1 page. Lien externe
Guerboukha, H., Nallappan, K., Seghilani, M., Azaña, J., & Skorobogatiy, M. A. (mars 2019). Low-loss terahertz lens and vortex generator using planar porous components [Communication écrite]. 8th International Conference on Optical Terahertz Science and Technology (OTST 2019), Santa Fe, New Mexico, U.S.A. Lien externe
Guerboukha, H., Nallappan, K., Cao, Y., Seghilani, M., Azana, J., & Skorobogatiy, M. A. (2019). Planar Porous Components for Low-Loss Terahertz Optics. Advanced Optical Materials, 7(15), 12 pages. Lien externe
Guerboukha, H., Nallappan, K., & Skorobogatiy, M. A. (mars 2019). Terahertz imaging with 45 pixels through spectral encoding of the k-space [Communication écrite]. 8th International Conference on Optical Terahertz Science and Technology (OTST 2019), Santa Fe, New Mexico, USA. Lien externe
Guerboukha, H., Nallappan, K., & Skorobogatiy, M. A. (septembre 2019). Toward real-time terahertz imaging: a comprehensive overview [Communication écrite]. 10th Iberoamerican Optics Meeting / 13th Latinamerican Meeting on Optics, Lasers and Applications/ Mexican Optics and Photonics Meeting (RIAO-OPTILAS-MOPM 2019), Cancùn, Mexico. Lien externe
Guerboukha, H., Nallappan, K., & Skorobogatiy, M. A. (avril 2018). Exploiting k-space/frequency duality in Fourier optics toward real-time compression-less terahertz imaging [Communication écrite]. Computational Imaging III, Orlando, FL (7 pages). Lien externe
Guerboukha, H., Nallappan, K., & Skorobogatiy, M. A. (2018). Exploiting k-space/frequency duality toward real-time terahertz imaging. Optica, 5(2), 109-116. Lien externe
Guerboukha, H., Nallappan, K., & Skorobogatiy, M. A. (2018). Toward real-time terahertz imaging. Advances in Optics and Photonics, 10(4), 843-938. Lien externe
Guerboukha, H., Nallappan, K., & Skorobogatiy, M. A. (août 2017). Fast compressionless reconstruction for terahertz imaging [Communication écrite]. 42nd International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2017), Cancun, Mexico (2 pages). Lien externe
Gannot, I., Li, J., Qu, H., & Skorobogatiy, M. A. (février 2016). Detection of analyte refractive index and concentration using liquid-core photonic Bragg fibers [Communication écrite]. Optical Fibers and Sensors for Medical Diagnostics and Treatment Applications XVI, San Francisco, California. Lien externe
Guerboukha, H., Markov, A., Hang, Q., & Skorobogatiy, M. A. (février 2016). Dynamic measurements at THz frequencies with a fast rotary delay line [Communication écrite]. Terahertz, RF, Millimeter and Submillimeter-Wave Technology and Applications IX, San Francisco, California (10 pages). Lien externe
Guerboukha, H., Markov, A., Qu, H., & Skorobogatiy, M. A. (juin 2015). Dynamic measurements at terahertz frequencies with a fast rotary delay line [Communication écrite]. Photonics North 2015, Ottawa, ON, Canada. Lien externe
Guerboukha, H., Markov, A., Hang, Q., & Skorobogatiy, M. A. (août 2015). Dynamic measurements at THz frequencies with a fast rotary delay line [Communication écrite]. 40th International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2015), Hong Kong (1 page). Lien externe
Gueboukha, H., Guofeng, Y., Skorobogata, O., & Skorobogatiy, M. A. (août 2015). Silk foam terahertz waveguides [Communication écrite]. 40th International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2015), Hong Kong (1 page). Lien externe
Guerboukha, H., Markov, A., Hang, Q., & Skorobogatiy, M. A. (2015). Time Resolved Dynamic Measurements at THz Frequencies using a Rotary Optical Delay Line. IEEE Transactions on Terahertz Science and Technology, 5(4), 564-572. Lien externe
Girard, M., & Skorobogatiy, M. A. (2014). Integrated terahertz multiparameter sensors using fiber/frequency selective surface couplers. Journal of Optics (United Kingdom), 16(9). Lien externe
Guerboukha, H., Yan, G., Skorobogata, O., & Skorobogatiy, M. A. (2014). Silk Foam Terahertz Waveguides. Advanced Optical Materials, 2(12), 1181-1192. Lien externe
Gorgutsa, S., Berzowska, J., & Skorobogatiy, M. A. (2013). Optical fibers for smart photonic textiles. Dans Multi-disciplinary know-how for smart textile developers (p. 70-90). Lien externe
Girarda, M., & Skorobogatiy, M. A. (septembre 2013). Probing frequency selective surfaces with terahertz subwavelength fibers [Communication écrite]. 2013 38th International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2013), Mainz, Germany (2 pages). Lien externe
Girard, M., & Skorobogatiy, M. A. (septembre 2013). Probing terahertz frequency selective surfaces with subwavelength optical fibers [Communication écrite]. IPC 2013. 26th IEEE Photonics Conference, Bellevue, WA, United states. Lien externe
Girard, M., & Skorobogatiy, M. A. (2013). Probing terahertz metamaterials with subwavelength optical fibers. Optics Express, 21(14), 17195-17211. Lien externe
Gorgutsa, S., & Skorobogatiy, M. A. (2013). Soft capacitance fibers for touch-sensitive smart textiles. Dans Multi-disciplinary know-how for smart textile developers (p. 154-188). Lien externe
Girard, M., & Skorobogatiy, M. A. (septembre 2013). Terahertz multiparameter sensors based on frequency selective surfaces coupled to subwavelength fibers [Communication écrite]. 2013 38th International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2013), Mainz, Germany (2 pages). Lien externe
Girard, M., & Skorobogatiy, M. A. (juillet 2013). Terahertz multiparameter sensors based on frequency selective surfaces interrogated with subwavelength fibers [Communication écrite]. Optical Sensors, Rio Grande, Puerto Rico. Lien externe
Guofeng, Y., Chiniforooshan, Y., Mikulic, P., Bock, W. J., & Skorobogatiy, M. A. (juillet 2013). THz Bragg gratings by CO₂ laser inscription and their application in paper quality monitoring [Communication écrite]. Optical Sensors, Rio Grande, Puerto Rico. Lien externe
Gorgutsa, S., Gu, J. F., & Skorobogatiy, M. A. (2012). A Woven 2D Touchpad Sensor and a 1D Slide Sensor Using Soft Capacitor Fibers. Smart Materials and Structures, 21(1), 10-10. Lien externe
Gauvreau, B., Guo, N., Schicker, K., Stoeffler, K., Boismenu, F., Ajji, A., Dubois, C., & Skorobogatiy, M. A. (juin 2009). Colorful photonic band gap fiber-based textiles [Communication écrite]. Conference on Lasers and Electro-Optics and 2009 Conference on Quantum Electronics and Laser Science Conference, Baltimore, MD, United states. Lien externe
Gauvreau, B., Desevedavy, F., Guo, N., Khadri, D., Hassani, A., & Skorobogatiy, M. A. (2009). High numerical aperture polymer microstructured fiber with three super-wavelength bridges. Journal of Optics. A, Pure and Applied Optics, 11(8), 085102-085102. Lien externe
Gauvreau, B., Guo, N., Schicker, K., Stoeffler, K., Boismenu, F., Ajji, A., Wingfield, R., Dubois, C., & Skorobogatiy, M. A. (2008). Color-Changing and Color-Tunable Photonic Bandgap Fiber Textiles. Optics Express, 16(20), 15677-15693. Lien externe
Gauvreau, B., Schicker, K., Guo, N., Dubois, C., Wingfield, R., & Skorobogatiy, M. A. (2008). Color-on-demand photonic textiles. Textile journal, 125, 70-81. Lien externe
Gauvreau, B., Khadri, D., Guo, N., & Skorobogatiy, M. A. (mai 2008). Suspended core high numerical aperture multimode polymer fiber [Communication écrite]. Conference on Lasers and Electro-Optics (CLEO 2008). Lien externe
Gauvreau, B., Hassani, A., Fehri, M. F., Kabashin, A., & Skorobogatiy, M. A. (2007). Photonic Bandgap Fiber-Based Surface Plasmon Resonance Sensors. Optics Express, 15(18), 11413-11426. Lien externe
Gao, Y., Guo, N., Gauvreau, B., Rajabian, M., Skorobogata, O., Pone, E., Zabeida, O., Martinu, L., Dubois, C., & Skorobogatiy, M. A. (2006). Consecutive Solvent Evaporation and Co-Rolling Techniques for Polymer Multilayer Hollow Fiber Preform Fabrication. Journal of Materials Research, 21(9), 2246-2254. Lien externe
Gao, Y., Guo, N., Gauvreau, B., Rajabian, M., Skorobogata, O., Pone, E., Zabeida, O., Martinu, L., Dubois, C., & Skorobogatiy, M. A. (septembre 2006). Consecutive solvent evaporation and co-rolling techniques for polymer multilayer hollow fiber preform fabrication [Communication écrite]. 15th International Conference on Plastic Optical Fibers, Seoul, Korea. Non disponible
Guo, N., Gao, Y., Dupuis, A., Pone, E., Lacroix, S., Dubois, C., & Skorobogatiy, M. A. (septembre 2006). Fabrication of the hollow all-polymer Bragg fibers [Communication écrite]. 15th International Conference on Plastic Optical Fibers, Seoul, Korea. Non disponible
Henri, R., Nallappan, K., Ponomarev, D. S., Guerboukha, H., Lavrukhin, D. V., Yachmenev, A. E., Khabibullin, R. A., & Skorobogatiy, M. A. (2021). Fabrication and Characterization of an 8 × 8 Terahertz Photoconductive Antenna Array for Spatially Resolved Time Domain Spectroscopy and Imaging Applications. IEEE Access, 9, 117691-117702. Disponible
Hang, Q., Bourgeois, J.-P., Rolland, J., Vlad, A., Gohy, J.-F., & Skorobogatiy, M. A. (novembre 2012). Flexible fiber batteries for applications in smart textiles [Communication écrite]. 2012 MRS Fall Meeting, Serction A: Complient Energy sources, Boston, USA. Publié dans MRS Online Proceedings Library, 1489. Lien externe
Hang, Q., Brastaviceanu, T., Bergeron, F., Olesik, J., & Skorobogatiy, M. A. (juillet 2013). Micro-displacement sensors based on plastic photonic bandgap Bragg fibers [Communication écrite]. Optical Sensors, Rio Grande, Puerto Rico. Lien externe
Hassani, A., & Skorobogatiy, M. A. (juin 2009). Ferroelectric PVDF-based Surface Plasmon Resonance-like integrated sensor at terahertz frequencies for gaseous analytes [Communication écrite]. Conference on Lasers and Electro-Optics and 2009 Conference on Quantum Electronics and Laser Science Conference, Baltimore, MD, United states. Lien externe
Hassani, A., & Skorobogatiy, M. A. (2009). Photonic crystal fiber-based plasmonic sensors for the detection of bio-layer thickness. Journal of the Optical Society of America. B, Optical Physics, 26(8), 1550-1557. Lien externe
Hassani, A., Dupuis, A., & Skorobogatiy, M. A. (2008). Low loss porous terahertz fibers containing multiple subwavelength holes. Applied Physics Letters, 92(7). Lien externe
Hassani, A., Dupuis, A., & Skorobogatiy, M. A. (mai 2008). Low loss THz fibers with multiple subwavelength holes [Communication écrite]. Conference on Lasers and Electro-Optics and Conference on Quantum Electronics and Laser Science (CLEO-QELS 2008), San Jose, CA, United States. Lien externe
Hassani, A., Gauvreau, B., & Skorobogatiy, M. A. (mai 2008). Novel photonic crystal fiber sensors using splitting of a degenerate plasmonic doublet [Communication écrite]. Conference on Lasers and Electro-Optics and Conference on Quantum Electronics and Laser Science (CLEO-QELS 2008), San Jose, CA, United States. Lien externe
Hassani, A., Gauvreau, B., Fehri, M. F., Kabashin, A., & Skorobogatiy, M. A. (2008). Photonic crystal fiber and waveguide-based surface plasmon resonance sensors for application in the visible and near-IR. Electromagnetics, 28(3), 198-213. Lien externe
Hassani, A., Dupuis, A., & Skorobogatiy, M. A. (2008). Porous Polymer Fibers for Low-Loss Terahertz Guiding. Optics Express, 16(9), 6340-6351. Lien externe
Hassani, A., & Skorobogatiy, M. A. (2008). Surface Plasmon Resonance-Like Integrated Sensor at Terahertz Frequencies for Gaseous Analytes. Optics Express, 16(25), 20206-20214. Lien externe
Hassani, A., Dupuis, A., & Skorobogatiy, M. A. (2008). Surface-Plasmon-Resonance-Like Fiber-Based Sensor at Terahertz Frequencies. Journal of the Optical Society of America. B, Optical Physics, 25(10), 1771-1775. Lien externe
Hassani, A., & Skorobogatiy, M. A. (2007). Design Criteria for Microstructured-Optical-Fiber-Based Surface-Plasmon-Resonance Sensors. Journal of the Optical Society of America. B, Optical Physics, 24(6), 1423-1429. Lien externe
Hassani, A., Pone, E., & Skorobogatiy, M. A. (2007). Heating of Microstructured Optical Fibers Due to Absorption of the Propagating Light. Journal of the Optical Society of America. B, Optical Physics, 24(4), 756-762. Lien externe
Hassani, A., Gauvreau, B., Fassi Fehri, M., Kabashin, A., & Skorobogatiy, M. A. (janvier 2007). Photonic bandgap fiber-based surface plasmon resonance sensors [Communication écrite]. Workshop on Nanophotonics and Plasmonics, Sao Paulo, Brazil. Non disponible
Hassani, A., & Skorobogatiy, M. A. (mai 2007). Practical design of microstructured optical fibers for surface plasmon resonance excitation [Communication écrite]. CLEO'07 Conference on lasers and electro-optics, Baltimore, Ma. Lien externe
Hassani, A., & Skorobogatiy, M. A. (mars 2007). Practical design of microstructured optical fibers for surface plasmon resonance sensing [Communication écrite]. OFCNFOEC 2007 : Optical Fiber Communication Conference and Exposition National Fiber Optic Engineers Conference, Anaheim, CA, USA. Lien externe
Hassani, A., & Skorobogatiy, M. A. (2006). Design of the microstructured optical fiber-based surface plasmon resonance sensors with enhanced microfluidics. Optics Express, 14(24), 11616-11621. Lien externe
Katyba, G. M., Lebedev, S. P., Kucheryavenko, A. S., Dolganova, I. N., Chernomyrdin, N. V., Burdanova, M. G., Spektor, I. E., Skorobogatiy, M. A., Kurlov, V. N., & Zaytsev, K. I. (2024). Terahertz refractometry of hard-to-access objects using the sapphire endoscope suitable for harsh environments. Applied Physics Letters, 124(24), 6 pages. Lien externe
Katyba, G. M., Skorobogatiy, M. A., Melikyants, D. G., Chernomyrdin, N. V., Perov, A. N., Yakovlev, E. V., Dolganova, I. N., Spektor, I. E., Tuchin, V. V., Kurlov, V. N., & Zaytsev, K. I. (2022). Superresolution Imaging Using a Tapered Bundle of High-Refractive-Index Optical Fibers. Physical Review Applied, 18(3), 10 pages. Lien externe
Kucheryavenko, A. S., Chernomyrdin, N. V., Gavdush, A. A., Alekseeva, A. I., Nikitin, P. V., Dolganova, I. N., Karalkin, P. A., Khalansky, A. S., Spektor, I. E., Skorobogatiy, M. A., Tuchin, V. V., & Zaytsev, K. I. (2021). Terahertz dielectric spectroscopy and solid immersion microscopy of ex vivo glioma model 1018: brain tissue heterogeneity. Biomedical Optics Express, 12(8), 5272-5289. Disponible
Kathirvel, N., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (mai 2018). Live Streaming of Uncompressed 4K Video Using Terahertz Wireless Links [Communication écrite]. IEEE International Conference on Communications (ICC 2018), Kansas City, MO (7 pages). Lien externe
Katyba, G. M., Zaytsev, K. I., Chernomyrdin, N. V., Shikunova, I. A., Komandin, G. A., Anzin, V. B., Lebedev, S. P., Spektor, I. E., Karasik, V. E., Yurchenko, S. O., Reshetov, I. V., Kurlov, V. N., & Skorobogatiy, M. A. (2018). Sapphire Photonic Crystal Waveguides for Terahertz Sensing in Aggressive Environments. Advanced Optical Materials, 6(22), 10 pages. Lien externe
Lavrukhin, D. V., Yachmenev, A. E., Glinskiy, I. A., Khabibullin, R. A., Goncharov, Y. G., Ryzhii, M., Otsuji, T., Spector, I. E., Shur, M., Skorobogatiy, M. A., Zaytsev, K., & Ponomarev, D. (2019). Terahertz photoconductive emitter with dielectric-embedded high-aspect-ratio plasmonic grating for operation with low-power optical pumps. AIP Advances, 9(1), 015112 (5 pages). Disponible
Lu, X., Qu, H., & Skorobogatiy, M. A. (août 2019). Piezoelectric Micro- and Nanostructured Fibers Fabricated from Thermoplastic Nanocomposites Using a Fiber Drawing Technique: Comparative Study and Potential Applications [Résumé]. 28th International Materials Research Congress, D7, Materials and Technologies for Energy Conversion Saving and Storage (MATECSS), Cancún, México. Lien externe
Lavrukhin, D. V., Yachmenev, A. E., Glinskiy, L. A., Khabibullin, R. A., Goncharov, Y. G., Ryzhii, M., Otsuji, T., Spektor, I. E., Shur, M., Nallappan, K., Skorobogatiy, M. A., Zaytsev, K. I., & Ponomarev, D. S. (mars 2019). Terahertz Photoconductive Emitter with Dielectric-Embedded High-Aspect-Ratio Plasmonic Grating for Operation with Low-Power Optical Pumps [Communication écrite]. International Workshop on Antenna Technology (iWAT 2019), Miami, FL, USA. Lien externe
Lu, X., Qu, H., & Skorobogatiy, M. A. (2018). Piezoelectric Micro- and Nanostructured Fibers Fabricated from Thermoplastic Nanocomposites Using a Fiber Drawing Technique: Comparative Study and Potential Applications. ECS Transactions, 86(16), 57-69. Lien externe
Lu, X., Qu, H., & Skorobogatiy, M. A. (mai 2018). Piezoelectric microstructured fibers via drawing of multimaterial preforms [Communication écrite]. Energy Harvesting and Storage : Materials, Devices and Applications VIII, Orlando, FL (10 pages). Lien externe
Lu, X., Qu, H., & Skorobogatiy, M. A. (2017). Piezoelectric microstructured fibers via drawing of multimaterial preforms. Scientific Reports, 7(1), 2907 (12 pages). Disponible
Li, J., Nallapan, K., Guerboukha, H., & Skorobogatiy, M. A. (mai 2017). 3D printed hollow core terahertz Bragg waveguide for surface sensing applications [Communication écrite]. CLEO: Applications and Technology (CLEO_AT 2017), San Jose, CA, United states. Lien externe
Li, J., Nallappan, K., Guerboukha, H., & Skorobogatiy, M. A. (2017). 3D printed hollow core terahertz Bragg waveguides with defect layers for surface sensing applications. Optics Express, 25(4), 4126-4144. Lien externe
Li, J., Ma, T., Nallapan, K., Guerboukha, H., & Skorobogatiy, M. A. (août 2017). 3D printed hollow core terahertz Bragg waveguides with defect layers for surface sensing applications [Communication écrite]. 42nd International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2017), Cancun, Mexico (1 page). Lien externe
Lu, X., Qu, H., & Skorobogatiy, M. A. (2017). Piezoelectric Micro- and Nanostructured Fibers Fabricated from Thermoplastic Nanocomposites Using a Fiber Drawing Technique: Comparative Study and Potential Applications. ACS Nano, 11(2), 2103-2114. Lien externe
Lu, X., Qu, H., & Skorobogatiy, M. A. (avril 2017). Smart fibers for textile-based micro-generators and compliant energy storage [Communication écrite]. Materials Research Society Spring Meeting & Exhibit (MRS 2017), Phoenix, Arizona. Lien externe
Li, J., Qu, H., & Skorobogatiy, M. A. (mai 2017). Squeezed hollow core photonic Bragg fiber for surface sensing applications [Communication écrite]. CLEO: Applications and Technology (CLEO_AT 2017), San Jose, CA, United states. Lien externe
Li, J., Qu, H., & Skorobogatiy, M. A. (2016). Squeezed hollow-core photonic Bragg fiber for surface sensing applications. Optics Express, 24(14), 15687-15701. Lien externe
Li, J., Qu, H., & Skorobogatiy, M. A. (2015). Simultaneous monitoring the real and imaginary parts of the analyte refractive index using liquid-core photonic bandgap Bragg fibers. Optics Express, 23(18), 22963-22976. Lien externe
Laurin, P., Girard, M., Markov, A., & Skorobogatiy, M. A. (septembre 2014). Hollow core terahertz optical fibers with hyperuniform disordered dielectric reflectors [Communication écrite]. International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2014), Tucson, AZ, United states. Lien externe
Liu, Y., Gorgutsa, S., Santato, C., & Skorobogatiy, M. A. (2012). Flexible, solid electrolyte-based lithium battery composed of LiFePO₄ cathode and Li₄Ti₅O₁₂ anode for applications in smart textiles. Journal of The Electrochemical Society, 159(4), A349-A356. Lien externe
Labonté, L., Pone, E., Skorobogatiy, M. A., Godbout, N., Lacroix, S., & Pagnoux, D. (avril 2009). Analysis of the birefringence of solid-core air-silica microstructured fibers [Communication écrite]. Photonic Crystal Fibers III, Prague, Czech republic. Lien externe
Loh, P.-R., Oskooi, A. F., Ibanescu, M., Skorobogatiy, M. A., & Johnson, S. G. (2009). Fundamental relation between phase and group velocity, and application to the failure of perfectly matched layers in backward-wave structures. Physical Review. E, Statistical, Nonlinear, and Soft Matter Physics, 79(6). Lien externe
Labonté, L., Pone, E., Skorobogatiy, M. A., Godbout, N., Lacroix, S., & Pagnoux, D. (avril 2009). Understanding form Birefringence of microstructured fibres [Communication écrite]. SPIE Europe : Optics+ Optoelectronics, Prague, Czech Republic. Non disponible
Morali, A., Mandal, A., Skorobogatiy, M. A., & Bodkhe, S. (2023). Unleashing the piezoelectric potential of PVDF: a study on phase transformation from gamma (γ) to beta (β) phase through thermal contact poling. RSC Advances, 13(44), 31234-31242. Disponible
Mandal, A., Morali, A., Skorobogatiy, M. A., & Bodkhe, S. (2023). 3D Printing of Polyvinylidene Fluoride-Based Piezoelectric Sensors for Noninvasive Continuous Blood Pressure Monitoring. Advanced Engineering Materials, 10 pages. Lien externe
Ma, T., Guerboukha, H., & Skorobogatiy, M. A. (mai 2017). 3D printed hollow-core terahertz optical waveguides with hyperuniform disordered dielectric reflectors [Communication écrite]. CLEO: Applications and Technology (CLEO_AT 2017), San Jose, CA, United states. Lien externe
Ma, T., Nallapan, K., Guerboukha, H., & Skorobogatiy, M. A. (2017). Analog signal processing in the terahertz communication links using waveguide Bragg gratings: example of dispersion compensation. Optics Express, 25(10), 11009-11026. Lien externe
Ma, T., Nallapan, K., Guerboukha, H., Skorobogatiy, M. A., & Qu, H. (mai 2017). Dispersion Compensation in Terahertz Communication Links Using Metallized 3D Printed Hollow Core Waveguide Bragg Gratings [Résumé]. CLEO: Science and Innovations 2017, San Jose, California. Lien externe
Ma, T., Guerboukha, H., Girard, M., Squires, A. D., Lewis, R. A., & Skorobogatiy, M. A. (2016). 3D Printed Hollow-Core Terahertz Optical Waveguides with Hyperuniform Disordered Dielectric Reflectors. Advanced Optical Materials, 4(12), 2085-2094. Lien externe
Ma, T., & Skorobogatiy, M. A. (octobre 2015). Dispersion Compensation in the Fiber-Based Terahertz Communication Links [Communication écrite]. IEEE International Conference on Ubiquitous Wireless Broadband (ICUWB 2015), Montréal, Québec (5 pages). Lien externe
Ma, T., Markov, A., Wang, L., & Skorobogatiy, M. A. (mai 2015). Graded index porous optical fibers - dispersion management in terahertz range [Communication écrite]. CLEO: QELS Fundamental Science (CLEO-QELS 2015), San Jose, CA, United states. Lien externe
Ma, T., Markov, A., Wang, L., & Skorobogatiy, M. A. (mai 2015). Graded index porous optical fibers-dispersion management in terahertz range [Communication écrite]. Conference on Lasers and Electro-Optics (CLEO 2015), Vancouver, Can.. Publié dans Optics Express, 23(6). Lien externe
Markov, A., Guerboukha, H., & Skorobogatiy, M. A. (mai 2015). Hybrid metal wire-dielectric THz fibers: Design and perspectives [Communication écrite]. CLEO : Applications and Technology (CLEO-AT 2015), San Jose, CA, United states. Lien externe
Ma, T., Skorobogatiy, M. A., & Wang, L. (septembre 2014). Graded index microstructured polymer fiber for terahertz applications [Communication écrite]. International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2014), Tucson, AZ, United states. Lien externe
Markov, A., Guerboukha, H., & Skorobogatiy, M. A. (2014). Hybrid metal wire-dielectric terahertz waveguides: Challenges and opportunities. Journal of the Optical Society of America B: Optical Physics, 31(11), 2587-2600. Lien externe
Markov, A., Guerboukha, H., Ma, T., & Skorobogatiy, M. A. (septembre 2014). Hybrid metal-dielectric THz fibers: Design and perspectives [Communication écrite]. International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2014), Tucson, AZ, United states. Lien externe
Markov, A., Yan, G., & Skorobogatiy, M. A. (septembre 2014). Low-loss THz waveguide Bragg grating using a two-wire waveguide and a paper grating [Communication écrite]. International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2014), Tucson, AZ, United states. Lien externe
Markov, A., & Skorobogatiy, M. A. (2013). Hybrid plasmonic terahertz fibers for sensing applications. Applied Physics Letters, 103(18). Lien externe
Markov, A., & Skorobogatiy, M. A. (2013). Two-wire terahertz fibers with porous dielectric support. Optics Express, 21(10), 12728-12743. Lien externe
Markov, A., Guerboukha, H., Argyros, A., & Skorobogatiy, M. A. (2013). A complementary study to "hybrid hollow core fibers with embedded wires as THz waveguides" and "two-wire terahertz fibers with porous dielectric support:" Comment. Optics Express, 21(23), 27802-27803. Lien externe
Markov, A., & Skorobogatiy, M. A. (juillet 2013). Hybrid plasmonic terahertz fibers for sensing [Communication écrite]. Optical Sensors, Rio Grande, Puerto Rico. Lien externe
Markov, A., Mazhorova, A., & Skorobogatiy, M. A. (2013). Planar porous THz waveguides for low-loss guidance and sensing applications. IEEE Transactions on Terahertz Science and Technology, 3(1), 96-102. Lien externe
Markov, A., & Skorobogatiy, M. A. (septembre 2013). Plasmonic two wire terahertz fibers with highly porous dielectric support [Communication écrite]. IPC 2013. 26th EEE Photonics Conference, Bellevue, WA, USA. Lien externe
Markov, A., & Skorobogatiy, M. A. (septembre 2013). Plasmonic two wire terahertz fibers with porous dielectric support [Communication écrite]. IRMMW-THz 2013. 38th International Conference on Infrared, Millimeter and Terahertz Waves, Mainz, Germany (2 pages). Lien externe
Markov, A., Gorgutsa, S., Qu, H., & Skorobogatiy, M. A. (juin 2013). Plasmonic two-wire terahertz fibers with highly porous dielectric support [Communication écrite]. CLEO 2013. Conference on lasers and electro optics, San Jose, CA, USA. Lien externe
Markov, A., & Skorobogatiy, M. A. (septembre 2013). Practical plasmonic terahertz fibers for sensing applications [Communication écrite]. 2013 38th International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2013), Mainz, Germany (2 pages). Lien externe
Mazhorova, A., Markov, A., Ung, B., Ng, A., Chinnappan, R., Zourob, M., & Skorobogatiy, M. A. (mai 2012). Label-free bacteria detection using evanescent mode of a suspended core terahertz fiber [Communication écrite]. CLEO: Science and Innovations, CLEO_SI 2012, San Jose, CA, United states. Lien externe
Mazhorova, A., Markov, A., Ng, A., Chinnappan, R., Skorobogata, O., Zourob, M., & Skorobogatiy, M. A. (2012). Label-Free Bacteria Detection Using Evanescent Mode of a Suspended Core Terahertz Fiber. Optics Express, 20(5), 5344-5355. Lien externe
Markov, A., Reinhardt, C., Ung, B., Evlyukhin, A. B., Cheng, W., Chichkov, B. N., & Skorobogatiy, M. A. (mai 2012). Photonic bandgap plasmonic waveguides [Communication écrite]. 2012 Conference on Lasers and Electro-Optics, CLEO 2012, San Jose, CA, United states (2 pages). Lien externe
Mazhorova, A., Markov, A., Ung, B., Roze, M., Gorgutsa, S., & Skorobogatiy, M. A. (2012). Thin chalcogenide capillaries as efficient waveguides from mid-infrared to terahertz. Journal of the Optical Society of America B: Optical Physics, 29(8), 2116-2123. Lien externe
Mazhorova, A., Markov, A., Ung, B., Rozé, M., Gorgutsa, S., & Skorobogatiy, M. A. (juin 2012). THZ wave guiding using hollow capillaries [Communication écrite]. Photonics North 2012, Montréal, Québec. Non disponible
Markov, A., Gorgutsa, S., Qu, H., & Skorobogatiy, M. A. (juin 2012). THz wire waveguides [Communication écrite]. Plasmonics, Gordon Research Conference, Maine, USA. Non disponible
Markov, A., Reinhardt, C., Ung, B., Evlyukhin, A. B., Cheng, W., Chichkov, B. N., & Skorobogatiy, M. A. (2011). Photonic bandgap plasmonic waveguides. Optics Letters, 36(13), 2468-2470. Lien externe
Mazhorova, A., Zourob, M., & Skorobogatiy, M. A. (juin 2011). Suspended core polyethylene fiber for bio-sensing applications in the terahertz region [Communication écrite]. Optical Sensors, Toronto, Canada. Lien externe
Mazhorova, A., Feng Gu, J., Dupuis, A., Peccianti, M., Tsuneyuki, O., Morandotti, R., Minamide, H., Tang, M., Wang, Y., Ito, H., & Skorobogatiy, M. A. (2010). Composite THz materials using aligned metallic and semiconductor microwires, experiments and interpretation. Optics Express, 18(24), 24632-24647. Lien externe
Mazhorova, A., Feng Gu, J., Gorgutsa, S., Peccianti, M., Morandotti, R., Ozaki, T., Tang, M., Minamide, H., Ito, H., & Skorobogatiy, M. A. (septembre 2010). THz metamaterials using aligned metallic or semiconductor nanowires [Communication écrite]. 35th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2010), Rome, Italy. Lien externe
Nallappan, K., & Skorobogatiy, M. A. (janvier 2023). Tunable Distributed Feedback Laser Based Frequency Hopping in Terahertz Communications [Communication écrite]. 2023 100th ARFTG Microwave Measurement Conference (ARFTG 2023), Las Vegas, NV, USA (4 pages). Lien externe
Nallappan, K., & Skorobogatiy, M. A. (2022). Photonics based frequency hopping spread spectrum system for secure terahertz communications. Optics Express, 30(15), 27028-27047. Lien externe
Nallappan, K., & Skorobogatiy, M. A. (juillet 2021). Comparison of Wired and Wireless Channel for Short Range Frequency Hopping Terahertz System [Communication écrite]. IEEE Photonics Society Summer Topicals Meeting Series (SUM 2021), Cabo San Lucas, Mexico (2 pages). Lien externe
Nallappan, K., Cao, Y., Xu, G., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (août 2021). Dielectric fiber-assisted terahertz communication links: Perspectives and challenges for onboard and secure communications [Communication écrite]. 4th IEEE Research and Applications of Photonics in Defense Conference (RAPID 2021), Miramar Beach, Florida (2 pages). Lien externe
Nallappan, K., Cao, Y., Xu, G., Guerboukha, H., Nerguizian, C., Skorobogatiy, M. A., Razeghi, M., & Baranov, A. N. Subwavelength solid core dielectric terahertz fibers for short range communications [Communication écrite]. SPIE Optical Engineering + Applications, San Diego, CA. Lien externe
Nallappan, K., Cao, Y., Xu, G., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (mai 2021). Terahertz Communications Using Rod-in-air Dielectric Subwavelength Fiber [Communication écrite]. Conference on Lasers and Electro-Optics (CLEO 2021), San Jose, CA, USA (2 pages). Lien externe
Nallappan, K., & Skorobogatiy, M. A. (août 2021). Wired channel modeling for frequency hopping system in secure terahertz communications [Communication écrite]. 4th IEEE Research and Applications of Photonics in Defense Conference (RAPID 2021), Miramar Beach, Florida (2 pages). Lien externe
Nallappan, K., Cao, Y., Xu, G., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (2020). Dispersion-limited versus power-limited terahertz communication links using solid core subwavelength dielectric fibers. Photonics Research, 8(11), 1757-1775. Lien externe
Nallappan, K., Cao, Y., Xu, G., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (mai 2020). High Bitrate Terahertz Fiber Communications [Présentation]. Dans SPIE Photonics North. Non disponible
Nallapan, K., Cao, Y., Xu, G., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (juillet 2020). Terahertz Communications Using Subwavelength Solid Core Fibers [Communication écrite]. IEEE International Symposium on Antennas and Propagation and North American Radio Science Meeting (APS/URSI 2020), Section FRUD.1A.3, Montréal, QC, Canada. Lien externe
Nallappan, K., Guerboukha, H., Cao, Y., Nerguizian, C., & Skorobogatiy, M. A. (janvier 2019). Experimental Demonstration of 5 Gbps Data Transmission Using Long Sub-Wavelength Fiber at 140 GHz [Communication écrite]. IEEE Radio Wireless Week 2019, Orlando, Florida, USA. Lien externe
Nallappan, K., Guerboukha, H., Cao, Y., Nerguizian, C., & Skorobogatiy, M. A. (janvier 2019). Experimental Demonstration of 5 Gbps Data Transmission Using Long Subwavelength Fiber at 140 GHz [Communication écrite]. IEEE Radio and Wireless Symposium (RWS 2019), Orlando, Florida (4 pages). Lien externe
Nallappan, K., Nerguizian, C., Guerboukha, H., Skorobogatiy, M. A., & Cao, Y. (mars 2019). High Bitrate Data Transmission Using Polypropylene Fiber in Terahertz Frequency Range [Communication écrite]. International Workshop on Antenna Technology (iWAT 2019), Miami, FL, United states. Lien externe
Nallappan, K., Cao, Y., Xu, G., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (janvier 2020). Increasing Reliability of Terahertz Communication Links Using Onboard Fiber Connectivity [Communication écrite]. 10th Annual Computing and Communication Workshop and Conference (CCWC 2020), Las Vegas, NV, USA. Lien externe
Nallappan, K., Guerboukha, H., & Skorobogatiy, M. A. (mars 2019). Reconfigurable Terahertz Array Antenna [Communication écrite]. International Workshop on Antenna Technology (iWAT 2019), Miami, FL, United states. Lien externe
Nallappan, K., Guerboukha, H., Cao, Y., Nerguizian, C., & Skorobogatiy, M. A. (mars 2019). Signal Transmission Using Solid Core Terahertz Waveguide [Résumé]. 8th International Conference on Optical Terahertz Science and Technology (OTST 2019), Santa Fe, NM, USA. Lien externe
Nallappan, K., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (2018). Live streaming of uncompressed HD and 4K videos using terahertz wireless links. IEEE Access, 6, 58030-58042. Disponible
Nallappan, K., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (mai 2018). Uncompressed HD and ultra-HD video streaming using terahertz wireless communications [Communication écrite]. 11th Global Symposium on Millimeter Waves (GSMM 2018), Boulder, CO (3 pages). Lien externe
Nallappan, K., Jingwen, L., Guerboukha, H., Markov, A., Petrov, B., Morris, D., & Skorobogatiy, M. A. (juin 2017). A dynamically reconfigurable terahertz array antenna for 2D-imaging applications [Communication écrite]. Photonics North (PN 2017), Ottawa, ON (1 page). Lien externe
Nallappan, K., Guerboukha, H., Seghilani, M., Tian, M., Azaña, J., Nerguizian, C., & Skorobogatiy, M. A. (août 2017). Multiplexing of terahertz wireless communication channels using vortex beams [Communication écrite]. 42nd International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2017), Cancun, Mexico (1 page). Lien externe
Nallappan, K., Guerboukha, H., Nerguizian, C., & Skorobogatiy, M. A. (août 2017). Practical implementation of live uncompressed 4K video transmission at 140 GHz using photonics technologies [Communication écrite]. 42nd International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2017), Cancun, Mexico (1 page). Lien externe
Ponomarev, D. S., Zaytsev, K., Skorobogatiy, M. A., Khabibullin, R. A., Glinskiy, I., & Otsuji, T. (juillet 2022). Optical-to-THz switches for pulse THz generation and detection [Communication écrite]. IEEE Photonics Society Summer Topicals Meeting Series (SUM 2022), Cabo San Lucas, Mexico (2 pages). Lien externe
Poulin, M., & Skorobogatiy, M. A. (2022). Surface Waves on Non Conducting Structured Interfaces. IEEE Transactions on Antennas and Propagation, 70(11), 10691-10705. Lien externe
Poulin, M., & Skorobogatiy, M. A. (août 2021). Ceramic-based metamaterial for THz sensing applications [Communication écrite]. Metamaterials, Metadevices and Metasystems 2021, San Diego, CA, USA (5 pages). Lien externe
Poulin, M., & Skorobogatiy, M. A. (avril 2021). Ceramic-based metamaterial for THz sensing applications [Communication écrite]. Biomedical Imaging and Sensing Conference 2021 (4 pages). Lien externe
Poulin, M., Giannacopoulos, S., & Skorobogatiy, M. A. (2019). Surface wave enhanced sensing in the terahertz spectral range: Modalities, materials, and perspectives. Sensors, 19(24), 23 pages. Lien externe
Pone, E., Hassani, A., Lacroix, S., & Skorobogatiy, M. A. (février 2008). Accurate modal analysis of microstructured optical fibers with the boundary integral method. [Communication écrite]. OFC/NFOEC 2008 Optical Fiber Communication Conference/National Fiber Optic Engineers Conference. Lien externe
Pone, E., Hassani, A., Lacroix, S., & Skorobogatiy, M. A. (mai 2008). A pressure sensor based on the loss birefringence of a microstructured optical fiber containing metal coated elliptical inclusions [Communication écrite]. Conference on Lasers and Electro-Optics and Conference on Quantum Electronics and Laser Science (CLEO-QELS 2008), San Jose, CA, United States. Lien externe
Pone, E., Hassani, A., Lacroix, S., Kabashin, A., & Skorobogatiy, M. A. (2007). Boundary Integral Method for the Challenging Problems in Bandgap Guiding, Plasmonics and Sensing. Optics Express, 15(16), 10231-10246. Lien externe
Pone, E., Hassani, A., & Skorobogatiy, M. A. (janvier 2007). Loss birefringence of a microstructured optical fiber containing metal coated elliptical inclusions: Prospective in pressure sensing [Communication écrite]. Workshop on Nanophotonics and Plasmonics, Sao Paulo, Brazil. Non disponible
Pone, E., Dubois, C., Guo, N., Gao, Y., Dupuis, A., Lacroix, S., & Skorobogatiy, M. A. (avril 2006). Drawing of hollow multilayered all-polymer fibers [Communication écrite]. Smart Nanotextiles. Symposium, San Francisco, CA, USA. Lien externe
Pone, E., Dubois, C., Guo, N., Gao, Y., Dupuis, A., Boismenu, F., Lacroix, S., & Skorobogatiy, M. A. (2006). Drawing of the Hollow All-Polymer Bragg Fibers. Optics Express, 14(13), 5838-5852. Lien externe
Pone, E., Dubois, C., Guo, N., Gao, A., Dupuis, A., Lacroix, S., & Skorobogatiy, M. A. (septembre 2006). Fabrication of the hollow all-polymer Bragg fibers [Communication écrite]. 32nd European Conference on Optical Communication, Cannes, France. Lien externe
Pone, E., Dubois, C., Guo, N., Lacroix, S., & Skorobogatiy, M. A. (2006). Newtonian and non-Newtonian models of the hollow all-polymer Bragg fiber drawing. Journal of Lightwave Technology, 24(12), 4991-4999. Lien externe
Qu, H., Lu, X., & Skorobogatiy, M. A. (août 2019). All-Solid Flexible Fiber-Shaped Lithium Ion Batteries [Communication écrite]. 28th International Materials Research Congress, D7, Materials and Technologies for Energy Conversion Saving and Storage (MATECSS), Cancún, México. Non disponible
Qu, H., Lu, X., & Skorobogatiy, M. A. (2018). All-solid flexible fiber-shaped lithium ion batteries. Journal of The Electrochemical Society, 165(3), A688-A695. Lien externe
Qu, H., & Skorobogatiy, M. A. (2017). Optics on the go: Active-color-changing textiles. Optics & Photonics News (September), 36-41. Lien externe
Qu, H., Hou, J., Lu, X., Tang, Y., Semenikhin, O., & Skorobogatiy, M. A. (avril 2017). Thin flexible lithium ion battery featuring graphite paper based current collectors with enhanced conductivity [Affiche]. Materials Research Society Spring Meeting & Exhibit (MRS 2017), Phoenix, Arizona. Non disponible
Qu, H., Hou, J., Tang, Y., Semenikhin, O., & Skorobogatiy, M. A. (2017). Thin flexible lithium-ion battery featuring graphite paper based current collectors with enhanced conductivity. Canadian Journal of Chemistry, 95(2), 169-173. Lien externe
Qu, H., Skorobogatiy, M. A., Deck-Leger, Z. L., & Caloz, C. (mai 2016). Frequency generation in a moving 2-dimensional photonic crystal [Communication écrite]. Photonic North (PN 2016), Québec City. Non disponible
Qu, H., Deck-Léger, Z.-L., Caloz, C., & Skorobogatiy, M. A. (2016). Frequency generation in moving photonic crystals. Journal of the Optical Society of America B: Optical Physics, 33(8), 1616-1626. Lien externe
Qu, H., Semenikhin, O., & Skorobogatiy, M. A. (2015). Flexible fiber batteries for applications in smart textiles. Smart Materials and Structures, 24(2). Lien externe
Qu, H., Li, J., & Skorobogatiy, M. A. (2015). Photonic bandgap fibers-a roadway to all-fiber refractometer systems for monitoring of liquid analytes. Dans Optofluidics, Sensors and Actuators in Microstructured Optical Fibers (p. 247-283). Lien externe
Qu, H., Yan, G. F., & Skorobogatiy, M. A. (2014). Interferometric fiber-optic bending/nano-displacement sensor using plastic dual-core fiber. Optics Letters, 39(16), 4835-4838. Lien externe
Qu, H., Brastaviceanu, T., Bergeron, F., Olesik, J., Pavlov, I., & Skorobogatiy, M. A. (septembre 2013). Micro-displacement sensors based on plastic photonic bandgap Bragg fibers [Communication écrite]. IPC 2013. 26th IEEE Photonics Conference, Bellevue, WA, United states. Lien externe
Qu, H., Brastaviceanu, T., Bergeron, F., Olesik, J., Pavlov, I., Ishigure, T., & Skorobogatiy, M. A. (2013). Photonic bandgap Bragg fiber sensors for bending/displacement detection. Applied Optics, 52(25), 6344-6349. Lien externe
Qu, H., Ung, B., Roze, M., & Skorobogatiy, M. A. (2012). All Photonic Bandgap Fiber Spectroscopic System for Detection of Refractive Index Changes in Aqueous Analytes. Sensors and Actuators B: Chemical, 161(1), 235-243. Lien externe
Qu, H., & Skorobogatiy, M. A. (juin 2012). All-photonic-bandgap-fiber sensor for detection of liquid refractive index3 [Communication écrite]. Photonics North 2012, Montréal, Québec. Non disponible
Qu, H., & Skorobogatiy, M. A. (juin 2012). Liquid-core low-refractive index-refractive index-contrast Bragg fiber sensor [Communication écrite]. Photonics North 2012, Montréal, Québec. Non disponible
Qu, H., Ung, B., & Skorobogatiy, M. A. (mai 2012). Photonic bandgap fiber bundle spectrometer [Communication écrite]. 2012 Conference on Lasers and Electro-Optics, CLEO 2012, San Jose, CA, United states (2 pages). Lien externe
Qu, H., & Skorobogatiy, M. A. (2012). Resonant Bio- and Chemical Sensors Using Low-Refractive-Index-Contrast Liquid-Core Bragg Fibers. Sensors and Actuators B: Chemical, 161(1), 261-268. Lien externe
Qu, H., & Skorobogatiy, M. A. (octobre 2011). All-polymer photonic bandgap Bragg fibers for bio-chemical sensors and spectrometers [Communication écrite]. 17th Microoptics Conference, MOC'11, Sendai, Japan. Lien externe
Qu, H., Ung, B., & Skorobogatiy, M. A. (juin 2011). Liquid filled hollow core photonic bandgap fiber sensor [Communication écrite]. Optical Sensors, Toronto, Canada. Lien externe
Qu, H., & Skorobogatiy, M. A. (2011). Liquid-core low-refractive-index-contrast Bragg fiber sensor. Applied Physics Letters, 98(20). Lien externe
Qu, H., Ung, B., Syed, I., Guo, N., & Skorobogatiy, M. A. (2010). Photonic Bandgap Fiber Bundle Spectrometer. Applied Optics, 49(25), 4791-4800. Lien externe
Reinhardt, C., Evlyukhin, A. B., Cheng, W., Birr, T., Markov, A., Ung, B., Skorobogatiy, M. A., & Chichkov, B. N. (2013). Bandgap-confined large-mode waveguides for surface plasmon-polaritons. Journal of the Optical Society of America B: Optical Physics, 30(11), 2898-2905. Lien externe
Reinhardt, C., Evlyukhin, A., Cheng, W., Kiyan, R., Kuznetsov, A., Chichkov, B., Skorobogatiy, M. A., & Markov, A. (janvier 2011). Plasmonic waveguides with photonic bandgap confinement [Communication écrite]. 3rd International Topical Meeting on Nanophotonics and Metamaterials (NanoMeta 2011), Tirol, Austria. Non disponible
Roze, M., Ung, B., Mazhorova, A., Walther, M., & Skorobogatiy, M. A. (2011). Suspended core subwavelength fibers: Towards practical designs for low-loss terahertz guidance. Optics Express, 19(10), 9127-9138. Lien externe
Skorobogatiy, M. A., Cao, Y., Guerboukha, H., & Nallappan, K. (mai 2020). Integrated optical circuits and fiberbased devices for upcoming THz communications [Présentation]. Dans SPIE Photonics North. Non disponible
Skorobogatiy, M. A. (août 2019). Bioriendly Silk Foams for bio-imaging and diagnostics using Terahertz waves [Communication écrite]. 28th International Materials Research Congress, C6, Materials for Health Applications: Biomedical Implants, Biomaterials, Therapeutics and Cosmetics, Cancún, México. Non disponible
Skorobogatiy, M. A. (août 2019). Pseudo-plasmonic materials with subwavelength patterning for applications in THz super-resolution imaging and ultra-fast wireless communications [Résumé]. 28th International Materials Research Congress, A1, Nanostructured Plasmonic Materials, Cancún, México. Non disponible
Skorobogatiy, M. A., Sadasivan, J., Nallappan, K., & Guerboukha, H. (mars 2019). Statistical denoising models for THz time-domain spectroscopy [Communication écrite]. 8th International Conference on Optical Terahertz Science and Technology (OTST 2019), Santa Fe, New Mexico, U.S.A. Lien externe
Skorobogatiy, M. A., & Semenikhin, O. A. (2018). Fiber-shaped lithium-ion batteries with metallic electrodes. (Rapport technique n° STPGP 447326-13). Lien externe
Skorobogatiy, M. A., Sadasivan, J., & Guerboukha, H. (2018). Statistical models for averaging of the pump-probe traces: Example of denoising in terahertz time-domain spectroscopy. IEEE Transactions on Terahertz Science and Technology, 8(3), 287-298. Lien externe
Soskind, Y. G., Olson, C., Guerboukha, H., Qu, H., & Skorobogatiy, M. A. (février 2016). Linear rotary optical delay lines [Communication écrite]. Photonic Instrumentation Engineering III, San Francisco, California. Lien externe
Skorobogatiy, M. A. (2014). Linear rotary optical delay lines. Optics Express, 22(10), 11812-11833. Lien externe
Shalaby, M., Peccianti, M., Ozturk, Y., Clerici, M., Al-Naib, I., Razzari, L., Mazhorova, A., Skorobogatiy, M. A., & Morandotti, R. (avril 2013). Broadband THz faraday rotation in a magnetic liquid [Communication écrite]. International Workshop on Optical Terahertz Science and Technologies (OTST 2013), Kyoto Terrsa, Japan. Non disponible
Shalaby, M., Peccianti, M., Ozturk, Y., Clerici, M., Al-Naib, I., Razzari, L., Mazhorova, A., Skorobogatiy, M. A., Ozaki, T., & Morandotti, R. (juin 2012). Magnetic field induced switching of terahertz pulses in a liquid [Communication écrite]. Photonics North 2012, Montréal, Québec. Non disponible
Skorobogatiy, M. A. (2012). Nanostructured and subwavelength waveguides : fundamentals and applications. Lien externe
Shalaby, M., Peccianti, M., Ozturk, Y., Razzari, L., Clerici, M., Mazhorova, A., Skorobogatiy, M. A., Ozaki, T., & Morandotti, R. (mai 2012). Polarization-sensitive magnetic field induced modulation of broadband THz pulses in liquid [Communication écrite]. 2012 Conference on Lasers and Electro-Optics, CLEO 2012, San Jose, CA, United states. Lien externe
Shalaby, M., Peccianti, M., Ozturk, Y., Clerici, M., Al-Naib, I., Razzari, L., Ozaki, T., Mazhorova, A., Skorobogatiy, M. A., & Morandotti, R. (2012). Terahertz Faraday Rotation in a Magnetic Liquid: High Magneto-Optical Figure of Merit and Broadband Operation in a Ferrofluid. Applied Physics Letters, 100(24). Lien externe
Skorobogatiy, M. A. (juin 2011). Designing living breathing T-shirt [Communication écrite]. Canadian Association of Physicists Congress, Saint-John, NF. Non disponible
Stoeffler, K., Dubois, C., Ajji, A., Guo, N., Boismenu, F., & Skorobogatiy, M. A. (2010). All-polymeric photonic bandgap polystyrene/polymethyl methacrylate Bragg fibers. SPE Plastic research online, 3 pages. Lien externe
Sayed, I., Berzowska, J., & Skorobogatiy, M. A. (avril 2010). Color tunable photonic textiles for wearable display applications [Communication écrite]. Three-Dimensional Imaging, Visualization, and Display 2010 and Display Technologies and Applications for Defense, Security, and Avionics IV, Orlando, Florida, USA. Lien externe
Skorobogatiy, M. A. (mai 2010). Design and Fabrication of Photonic Crystal Fibers for Plasmonic Sensing, Applications from the Visible to THz [Communication écrite]. Conference on Lasers and Electro-Optics (CLEO), San Jose, California. Lien externe
Stoeffler, K., Dubois, C., Ajji, A., Guo, N., Boismenu, F., & Skorobogatiy, M. A. (2010). Fabrication of all-polymeric photonic bandgap Bragg fibers using rolling of coextruded PS/PMMA multilayer films. Polymer Engineering and Science, 50(6), 1122-1127. Lien externe
Sayed, I., Berzowska, J., & Skorobogatiy, M. A. (2010). Jacquard-woven photonic bandgap fiber displays. Research Journal of Textile and Apparel, 14(4), 97-97. Lien externe
Skorobogatiy, M. A. (2010). Resonant bio-chemical sensors based on Photonic Bandgap waveguides and fibers. Dans Optical guided-wave Chemical and Biosensors II (Vol. 8, p. 43-72). Lien externe
Skorobogatiy, M. A. (2010). Single step fabrication of highly sensitive biosensors. SPIE Newsroom. Lien externe
Skorobogatiy, M. A., & Dupuis, A. (2009). Ferroelectric all-polymer hollow Bragg fibers for terahertz guidance. (Demande de brevet no US20090097809). Lien externe
Skorobogatiy, M. A., & Yang, J. (2009). Fundamentals of photonic crystal guiding. Lien externe
Skorobogatiy, M. A. (2009). Microstructured and photonic bandgap fibers for applications in the resonant bio- and chemical sensors. Journal of Sensors, 2009, 524237 (20 pages). Disponible
Skorobogatiy, M. A. (octobre 2009). Polymer microstructured optical fibers-overview of the novel geometries and functional plastics for a variety of applications including photonic textiles and high bit rate data communications, low-loss mid-ir and thz guiding, as well as plasmonic sensing and nanophotonics [Communication écrite]. 15th Microoptics Conference, Tokyo, Japan. Non disponible
Shi, L., Kabashin, A., & Skorobogatiy, M. A. (2009). Spectral, amplitude and phase sensitivity of a plasmonic gas sensor in a metallic photonic crystal slab geometry: Comparison of the near and far field phase detection strategies. Sensors and Actuators, B: Chemical, 143(1), 76-86. Lien externe
Shi, L., Pottier, P., Skorobogatiy, M. A., & Peter, Y.-A. (2009). Tunable structures comprising two photonic crystal slabs - Optical study in view of multi-analyte enhanced detection. Optics Express, 17(13), 10623-10632. Lien externe
Skorobogatiy, M. A., Saitoh, K., & Koshiba, M. (2008). Full-Vectorial Coupled Mode Theory for the Evaluation of Macro-Bending Loss in Multimode Fibers. Application to the Hollow-Core Photonic Bandgap Fibers. Optics Express, 16(19), 14945-14953. Lien externe
Shi, L., Pottier, P., Peter, Y.-A., & Skorobogatiy, M. A. (2008). Guided-Mode Resonance Photonic Crystal Slab Sensors Based on Bead Monolayer Geometry. Optics Express, 16(22), 17962-17971. Lien externe
Skorobogatiy, M. A., & Kabashin, A. (2008). Plasmon excitation by the gaussian-like core mode of a photonic crystal waveguide. (Brevet no US7460238). Lien externe
Skorobogatiy, M. A., & Guo, N. (mai 2007). Bandwidth Enhancement by Differential Mode Attenuation in Multimode Photonic Crystal Bragg Fibers [Communication écrite]. Conference on lasers and electro-optics (CLEO'07), Baltimore, Ma. Publié dans Optics Letters, 32(8). Lien externe
Skorobogatiy, M. A., Dupuis, A., & Guo, N. (mars 2007). Design and fabrication of ferroelectric all-polymer hollow Bragg fibers for THz guidance [Communication écrite]. OFCNFOEC 2007 : Optical Fiber Communication Conference and Exposition National Fiber Optic Engineers Conference, Anaheim, CA, USA. Lien externe
Skorobogatiy, M. A., & Dupuis, A. (2007). Ferroelectric All-Polymer Hollow Bragg Fibers for Terahertz Guidance. Applied Physics Letters, 90(11), 13514-13514. Lien externe
Skorobogatiy, M. A. (mai 2007). Ferroelectric all-polymer hollow Bragg fibers for THz [Communication écrite]. CLEO'07 Conference on lasers and electro-optics, Baltimore, Ma. Lien externe
Skorobogatiy, M. A., & Kabashin, A. (mai 2007). Photon crystal waveguide-based surface plasmon resonance biosensor [Communication écrite]. CLEO'07 Conference on lasers and electro-optics, Baltimore, MD, USA. Lien externe
Skorobogatiy, M. A. (mai 2006). Efficient antiguiding without omnidirectional reflectors [Communication écrite]. Conference on Lasers and Electro-Optics and Conference on Quantum Electronics and Laser Science (CLEO-QELS 2006), Long Beach, CA, USA. Lien externe
Saitoh, K., Florous, N. J., Koshiba, M., & Skorobogatiy, M. A. (2006). Multi-Core Photonic Band Gap Fiber Splitters Based on Highly-Selective Non-Proximity Resonant Coupling. Denshi Joho Tsushin Gakkai Taikai Koen Ronbunshu (1), 222-222. Lien externe
Saitoh, K., Florous, N. J., Koshiba, M., & Skorobogatiy, M. A. (juillet 2006). Multi-Core Photonic Band-Gap Fiber Splitters Based on Highly-Selective Non-Proximity Resonant Coupling [Communication écrite]. 11th OptoElectronics and Communications Conference, Taiwan. Lien externe
Saitoh, K., Florous, N. J., Murao, T., Koshiba, M., & Skorobogatiy, M. A. (septembre 2006). Non-Proximity Resonant Tunneling in Multi-Core Photonic Band Gap Fibers: A Revolutionary Technology for All-Fiber Integrated Assemblies [Communication écrite]. European Conference on Optical Communication, Cannes, France. Lien externe
Skorobogatiy, M. A., & Kabashin, A. (2006). Photon crystal waveguide-based surface plasmon resonance biosensor. Applied Physics Letters, 89(14), 143518-1. Lien externe
Skorobogatiy, M. A., & Kabashin, A. (avril 2006). Plasmon excitation by the Gaussian-like core mode of a photonic crystal waveguide [Communication écrite]. European Optical Society Topical Meeting on Molecular Plasmonic Devices, Switzerland. Non disponible
Skorobogatiy, M. A., & Kabashin, A. (2006). Plasmon excitation by the Gaussian-like core mode of a photonic crystal waveguide. Optics Express, 14(18), 8419-8424. Lien externe
Skorobogatiy, M. A., & Kabashin, A. (octobre 2006). Plasmon excitation by the Gaussian-like core mode of a photonic crystal waveguide or a fiber [Communication écrite]. 18th International Conference on Optical Fiber Sensors, Cancun, Mexico. Lien externe
Skorobogatiy, M. A. (juin 2006). Polymer microstructured fibers for bio-medical applications : Overview of the new materials, structures and ideas [Communication écrite]. 61st Annual Congress of the Canadian Association of Physicists, Section : Biomedical Optics, St-Catherines, ON, Canada. Non disponible
Skorobogatiy, M. A., Saitoh, K., & Koshiba, M. (2006). Transverse Light Guides in Microstructured Optical Fibers. Optics Letters, 31(3), 314-316. Lien externe
Skorobogatiy, M. A., Saitoh, K., & Koshiba, M. (2006). Transverse lightwave circuits in microstructured optical fibers: Resonator arrays. Optics Express, 14(4), 1439-1450. Lien externe
Skorobogatiy, M. A., Saitoh, K., & Koshiba, M. (mai 2006). Transverse lightwave circuits in MOFs: waveguides and resonator arrays [Communication écrite]. Conference on Lasers and Electro-Optics and Conference on Quantum Electronics and Laser Science (CLEO-QELS 2006), Long Beach, CA, USA. Lien externe
Skorobogatiy, M. A., Saitoh, K., & Koshiba, M. (janvier 2005). Coupling Between Two Collinear Air-Core Bragg Fibers [Communication écrite]. Photonic Crystal Materials and Devices III, San Jose, California, USA. Lien externe
Saitoh, K., Florous, N. J., Koshiba, M., & Skorobogatiy, M. A. (2005). Design of Narrow Band-Pass Filters Based on the Resonant-Tunneling Phenomenon in Multicore Photonic Crystal Fibers. Optics Express, 13(25), 10327-10335. Lien externe
Skorobogatiy, M. A. (2005). Design Principles of Multifiber Resonant Directional Couplers With Hollow Bragg Fibers: Example of a 3x3 Coupler. Optics Letters, 30(21), 2849-2851. Lien externe
Skorobogatiy, M. A. (2005). Efficient Antiguiding of Te and Tm Polarizations in Low-Index Core Waveguides Without the Need for an Omnidirectional Reflector. Optics Letters, 30(22), 2991-2993. Lien externe
Skorobogatiy, M. A., Jacobs, S. A., Johnson, S. G., Anastassiou, C., & Temelkuran, B. (2005). Heating of hollow photonic Bragg fibers from field propagation, coupling, and bending. Journal of Lightwave Technology, 23(11), 3517-3525. Lien externe
Skorobogatiy, M. A. (janvier 2005). Modelling the impact of imperfections in high index-contrast photonic waveguides [Communication écrite]. Photonic Crystal Materials and Devices III, San Jose, CA, United States. Lien externe
Skorobogatiy, M. A., Park, I. J., & Joannopoulos, J. D. (2005). The nature of a floating electron. Computational Materials Science, 32(1), 96-106. Lien externe
Skorobogatiy, M. A., Begin, G., & Talneau, A. (2005). Statistical analysis of geometrical imperfections from the images of 2D photonic crystals. Optics Express, 13(7), 2487-2502. Lien externe
Skorobogatiy, M. A., Saitoh, K., & Koshiba, M. (2005). Transverse lightwave circuits in microstructured optical fibers: Waveguides. Optics Express, 13(19), 7506-7515. Lien externe
Skorobogatiy, M. A. (2004). Hollow Bragg Fiber Bundles: When Coupling Helps and When It Hurts. Optics Letters, 29(13), 1479-1481. Lien externe
Skorobogatiy, M. A., Saitoh, K., & Koshiba, M. (2004). Coupling between two collinear air-core Bragg fibers. Journal of the Optical Society of America. B, Optical Physics, 21(12), 2095-2101. Lien externe
Skorobogatiy, M. A., Saitoh, K., & Koshiba, M. Hollow Bragg Fiber Bundles: When Coupling Helps and When It Hurts [Communication écrite]. Photonics North 2004, Ottawa, Ontario, Canada. Lien externe
Skorobogatiy, M. A. (2004). Modeling the impact of imperfections in high-index-contrast photonic waveguides. Physical Review. E, Statistical Physics, Plasmas, Fluids, and Related Interdisciplinary Topics, 70(4), 46609.1-46609.9-46609.1-46609.9. Lien externe
Skorobogatiy, M. A., Jacobs, S. A., Johnson, S. G., Meunier, M., & Fink, Y. (avril 2004). Modeling the impact of manufacturing imperfections on photonic crystal device performance: design of perturbation-tolerant PGB components [Communication écrite]. Photonic Crystal Materials and Nanostructures, Strasbourg, France. Lien externe
Skorobogatiy, M. A., Saitoh, K., & Koshiba, M. (2004). Resonant Directional Coupling of Hollow Bragg Fibers. Optics Letters, 29(18), 2112-2114. Lien externe
Skorobogatiy, M. A., Anastassiou, C., Johnson, S. G., Weisberg, O., Engeness, T. D., Jacobs, S. A., Ahmad, R. U., & Fink, Y. (2003). Quantitative Characterization of Higher-Order Mode Converters in Weakly Multimoded Fibers. Optics Express, 11(22), 2838-2847. Lien externe
Tian, M., Nallapan, K., Guerboukha, H., & Skorobogatiy, M. A. (août 2017). Metallized 3D printed hollow core waveguide Bragg grating for dispersion compensation in terahertz range [Communication écrite]. 42nd International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2017), Cancun, Mexico (1 page). Lien externe
Ulitko, V. E., Musina, G. R., Masalov, V. M., Gavdush, A. A., Emelchenko, G. A., Bukin, V. V., Kurlov, V. N., Skorobogatiy, M. A., Katyba, G. M., & Zaytsev, K. I. (2023). Moisture adsorption by porous terahertz optical materials: a case study of artificial SiO2 opals. Optical Materials Express, 13(4), 1163-1176. Lien externe
Ulitko, V. E., Katyba, G. M., Zhelnov, V. A., Shmytko, I. M., Emelchenko, G. A., Spector, I. E., Masalov, V. M., Kurlov, V. N., Zaytsev, K. I., & Skorobogatiy, M. A. (2021). Opal-based terahertz optical elements fabricated by self-assembly of porous SiO2 nanoparticles. Optics Express, 29(9), 13764-13777. Lien externe
Ulitko, V. E., Zotov, A. K., Gavdush, A. A., Katyba, G. M., Komandin, G. A., Spektor, I. E., Shmytko, I. M., Emelchenko, G. A., Dolganova, I. N., Skorobogatiy, M. A., Kurlov, V. N., Masalov, V. M., & Zaytsev, K. I. (2020). Nanoporous SiO₂ based on annealed artificial opals as a favorable material platform of terahertz optics. Optical Materials Express, 10(9), 2100-2113. Lien externe
Ung, B., & Skorobogatiy, M. A. (2013). Transmission and propagation of terahertz wabes in plastic waveguides. Dans Handbook of terahertz technology for imaging, sensing and communications . Lien externe
Ung, B., Mazhorova, A., Dupuis, A., Rozé, M., & Skorobogatiy, M. A. (2011). Polymer microstructured optical fibers for terahertz wave guiding. Optics Express, 19(26), B848-B861. Lien externe
Ung, B., & Skorobogatiy, M. A. (octobre 2011). Design and fabricationof photonic crystal and plasmonic waveguides for bio and chemical sensing; applications from the visible to THz spectral range [Communication écrite]. Frontiers in Optics (FiO) 2011/ Laser Science (LS) XXVII, San Jose, California, USA. Lien externe
Ung, B., & Skorobogatiy, M. A. (2011). Extreme nonlinear optical enhancement in chalcogenide glass fibers with deep-subwavelength metallic nanowires. Optics Letters, 36(13), 2527-2529. Lien externe
Ung, B., & Skorobogatiy, M. A. (2011). Extreme optical nonlinearities in chalcogenide glass fibers embedded with metallic and semiconductor nanowires. Applied Physics Letters, 99(12). Lien externe
Ung, B., & Skorobogatiy, M. A. (mai 2011). Giant nonlinear optical enhancement in chalcogenide glass fibers with deep-subwavelength metallic nanowires [Communication écrite]. Conference on Lasers and Electro-Optics, CLEO 2011, Baltimore, MD, United states. Lien externe
Ung, B., Dupuis, A., Stoeffler, K., Dubois, C., & Skorobogatiy, M. A. (2011). High-refractive-index composite materials for terahertz waveguides: Trade-off between index contrast and absorption loss. Journal of the Optical Society of America B: Optical Physics, 28(4), 917-921. Lien externe
Ung, B., Mazhorova, A., Roze, M., Dupuis, A., & Skorobogatiy, M. A. (septembre 2011). Plastic fibers for terahertz wave guiding [Communication écrite]. 37th European Conference on Optical Communication and Exhibition, ECOC 2011, Geneva, Switzerland. Lien externe
Ung, B., Rozé, M., Mazhorova, A., Walther, M., & Skorobogatiy, M. A. (mai 2011). Suspended core polymer fibers with isolated mode for terahertz guiding [Communication écrite]. Conference on Lasers and Electro-Optics, CLEO 2011, Baltimore, MD, United states. Lien externe
Ung, B., Rozé, M., Mazhorova, A., Walther, M., & Skorobogatiy, M. A. (juin 2011). Suspended core subwavelength fibers for practical low-loss terahertz guidance [Communication écrite]. Optical Sensors, Toronto, Canada. Lien externe
Ung, B., Rozé, M., Mazhorova, A., Walther, M., & Skorobogatiy, M. A. (2011). Suspended core subwavelength plastic fibers for THz guidance. Optics & Photonics News, 41-41. Lien externe
Ung, B., & Skorobogatiy, M. A. (2010). Chalcogenide microporous fibers for linear and nonlinear applications in the mid-infrared. Optics Express, 18(8), 8647-8659. Lien externe
Ung, B., & Skorobogatiy, M. A. (mai 2010). Chalcogenide Microporous Fibers for Nonlinear Applications in Mid-infrared [Communication écrite]. Conference on Lasers and Electro-Optics (CLEO), San Jose, California. Lien externe
Ung, B., Dupuis, A., & Skorobogatiy, M. A. (septembre 2010). High refractive index titania-doped polymers for THz hollow Bragg fibers: How absorption losses limit the index contrast [Communication écrite]. 35th International Conference on Infrared, Millimeter, and Terahertz Waves (IRMMW-THz 2010), Rome. Lien externe
Xu, G., & Skorobogatiy, M. A. (2023). 3D printing technique and its application in the fabrication of THz fibers and waveguides. Journal of Applied Physics, 133(21), 210901 (18 pages). Lien externe
Xu, G., & Skorobogatiy, M. A. (2023). Continuous fabrication of polarization maintaining fibers via an annealing improved infinity additive manufacturing technique for THz communications. Optics Express, 31(8), 12894-12911. Lien externe
Xu, G., Nallappan, K., Cao, Y., & Skorobogatiy, M. A. (janvier 2023). Infinity Additive Manufacturing of Polarization Maintaining Fibers for THz Communications [Communication écrite]. IEEE Radio and Wireless Symposium (RWS 2023), Las Vegas, NV, USA. Lien externe
Xu, G., Nallappan, K., Cao, Y., & Skorobogatiy, M. A. (2022). Infinity additive manufacturing of continuous microstructured fiber links for THz communications. Scientific Reports, 12(1), 4551 (13 pages). Lien externe
Xu, G., & Skorobogatiy, M. A. (2022). Wired THz Communications. Journal of Infrared Millimeter and Terahertz Waves, 43(9-10), 728-778. Lien externe
Xu, G., Nallappan, K., Cao, Y., & Skorobogatiy, M. A. (juillet 2021). Continuous Fabrication of Microstructured Waveguides for THz Communications Using Infinite 3D Printing [Communication écrite]. IEEE Photonics Society Summer Topicals Meeting Series (SUM 2021), Cabo San Lucas, Mexico (2 pages). Lien externe
Xu, G., Cao, Y., Nallappan, K., & Skorobogatiy, M. A. (octobre 2021). Continuous Fabrication of Suspended Core Polypropylene Fiber for THz Communications [Communication écrite]. IEEE Photonics Conference (IPC 2021), Vancouver, BC, Canada (2 pages). Lien externe
Xu, G., Nallappan, K., Cao, Y., & Skorobogatiy, M. A. (mai 2020). 3D printed suspended-core polypropylene fiber for THz communication system [Présentation]. Dans SPIE Photonics North. Non disponible
Yetisen, A. K., Qu, H., Manbachi, A., Butt, H., Dokmeci, M. R., Hinestroza, J. P., Skorobogatiy, M. A., Khademhosseini, A., & Yun, S. H. (2016). Nanotechnology in textiles. ACS Nano, 10(3), 3042-3068. Lien externe
Yan, G., Markov, A., Chinifooroshan, Y., Tripathi, S. M., Bock, W. J., & Skorobogatiy, M. A. (2013). Low-loss terahertz waveguide Bragg grating using a two-wire waveguide and a paper grating. Optics Letters, 38(16), 3089-3092. Lien externe
Yan, G., Markov, A., Chinifooroshan, Y., Tripathi, S. M., Bock, W. J., & Skorobogatiy, M. A. (2013). Resonant THz sensor for paper quality monitoring using THz fiber Bragg gratings. Optics Letters, 38(13), 2200-2202. Lien externe
Yan, G., Chinifooroshan, Y., Tripathi, S. M., Bock, W. J., & Skorobogatiy, M. A. (septembre 2013). Resonant THz sensor for paper quality monitoring using THz fiber Bragg gratings [Communication écrite]. IPC 2013. 26th IEEE Photonics Conference, Bellevue, WA, United states. Lien externe
Yan, G., Chinifooroshan, Y., Mikulic, P., Bock, W. J., & Skorobogatiy, M. A. (septembre 2013). THz Bragg gratings by CO2 laser inscription and their application to monitoring of paper quality [Communication écrite]. 2013 38th International Conference on Infrared, Millimeter and Terahertz Waves (IRMMW-THz 2013), Mainz, Germany (2 pages). Lien externe
Zhelnov, V. A., Ulitko, V. E., Skorobogatiy, M. A., Zaytsev, K. I., & Chernomyrdin, N. V. (2024). Spatial resolution limit for a solid immersion lens. Applied Optics, 63(30), 7893-7899. Lien externe
Zhelnov, V. A., Chernomyrdin, N. V., Katyba, G. M., Gavdush, A. A., Bukin, V. V., Garnov, S. V., Spektor, I. E., Kurlov, V. N., Skorobogatiy, M. A., & Zaytsev, K. I. (novembre 2023). Deeply subwavelength terahertz solid immersion microscopy using rutile optics [Communication écrite]. IEEE Photonics Conference (IPC 2023), Orlando, FL, USA (2 pages). Lien externe
Zhelnov, V. A., Chernomyrdin, N. V., Katyba, G. M., Gavdush, A. A., Bukin, V. V., Garnov, S. V., Spektor, I. E., Kurlov, V. N., Skorobogatiy, M. A., & Zaytsev, K. I. (2023). Hemispherical Rutile Solid Immersion Lens for Terahertz Microscopy with Superior 0.06–0.11λ Resolution. Advanced Optical Materials. Lien externe
Zhelnov, V. A., Zaytsev, K. I., Kucheryavenko, A. S., Katyba, G. M., Dolganova, I. N., Ponomarev, D. S., Kurlov, V. N., Skorobogatiy, M. A., & Chernomyrdin, N. V. (2021). Object-dependent spatial resolution of the reflection-mode terahertz solid immersion microscopy. Optics Express, 29(3), 3553-3566. Lien externe
Zaytsev, K. I., Kurlov, V. N., Skorobogatiy, M. A., Reshetov, I. V., & Tuchin, V. V. (2021). Special Section Guest Editorial: Advances in Terahertz Biomedical Science and Applications. Journal of Biomedical Optics, 26(4), 4 pages. Lien externe
Zhang, E., Cao, Y., Caloz, C., & Skorobogatiy, M. A. (2020). Erratum: Improving thermo-optic properties of smart windows via coupling to radiative coolers: Publishers Note (Applied Optics(2020) 59 (D210)Doi: 10.1364/AO.382050). Applied Optics, 59(13), 1 page. Lien externe
Zhang, E., Cao, Y., Caloz, C., & Skorobogatiy, M. A. (2020). Improving thermo-optic properties of smart windows via coupling to radiative coolers. Applied Optics, 59(13), D210-D220. Lien externe
Zaytsev, K. I., Katyba, G. M., Chernomyrdin, N. V., Dolganova, I. N., Kucheryavenko, A. S., Rossolenko, A. N., Tuchin, V. V., Kurlov, V. N., & Skorobogatiy, M. A. (2020). Overcoming the Abbe Diffraction Limit Using a Bundle of Metal-Coated High-Refractive-Index Sapphire Optical Fibers. Advanced Optical Materials, 8(18), 10 pages. Lien externe
Zaytsev, K. I., Dolganova, I. N., Chernomyrdin, N. V., Katyba, G. M., Gavdush, A. A., Cherkasova, O. P., Komandin, G. A., Shchedrina, M. A., Khodan, A. N., Ponomarev, D. S., Reshetov, I. V., Karasik, V. E., Skorobogatiy, M. A., Kurlov, V. N., & Tuchin, V. V. (février 2020). The potentials and limitations of terahertz imaging for diagnosis of neoplasms [Communication écrite]. SPIE Medical Imaging, Houston, Texas, USA. Lien externe
Zaytsev, K. I., Dolganova, I. N., Chernomyrdin, N. V., Katyba, G. M., Gavdush, A. A., Cherkasova, O. P., Komandin, G. A., Shchedrina, M. A., Khodan, A. N., Ponomarev, D. S., Reshetov, I. V., Karasik, V. E., Skorobogatiy, M. A., Kurlov, V. N., & Tuchin, V. V. (2020). The progress and perspectives of terahertz technology for diagnosis of neoplasms: A review. Journal of Optics (United Kingdom), 22(1), 45 pages. Lien externe
Zaytsev, K. I., Katyba, G. M., Chernomyrdin, N. V., Dolganova, I. N., Kucheryavenko, A. S., Rossolenko, A. N., Tuchin, V. V., Kurlov, V. N., & Skorobogatiy, M. A. (septembre 2020). Sapphire fiber bundles for terahertz imaging with spatial resolution beyond the Abbe limit [Résumé]. Chinese-Russian Workshop on Biophotonics and Biomedical Optics 2020. Lien externe