Source: http://fiberfuse.info/chronologicaltableof/papers.html
Timestamp: 2019-04-19 04:31:10+00:00

Document:
Works of numerical calculations are listed in another table separately.
Remote detection of fiber fuse, and protecting optical fibers.
In 秋季第66回応用物理学会学術講演会講演予稿集, volume 0, page 1, 富山県富山市, September 2009a.
Kazi S. Abedin and Toshio Morioka.
Remote detection of fiber fuse propagating in optical fibers.
In Proceedings of Optical Fiber Communication/National Fiber Optic Engineers Conference, March 2009.
Kazi S. Abedin and Masataka Nakazawa.
Real time monitoring of a fiber fuse using an optical time-domain reflectometer.
Optics Express, 18 (20): 21315-21321, September 2010.
Kazi S. Abedin, T. Miyazaki, and M. Nakazawa.
Measurements of spectral broadening and Doppler shift of backreflections from a fiber fuse using heterodyne detection.
Optics Letters, 34 (20): 3157-3159, October 2009a.
Kazi S. Abedin, M. Nakazawa, and T. Miyazaki.
Backreflected radiation due to a propagating fiber fuse.
Optics Express, 17 (8): 6525-6531, April 2009b.
Remote sensing of fiber fuse propagation using RF detection.
電子情報通信学会技術研究報告 OPE 光エレクトロニクス, 109 (159): 43-46, July 2009b.
N. Akhmediev, P. St. J. Russell, M. Taki, and J. M. Soto-Crespo.
Heat dissipative solitons in optical fibers.
Physics Letters A, 372 (9): 1531-1534, September 2008.
Paulo André, Ana Rocha, Fátima Domingues, and Margarida Facão.
Thermal effects in optical fibres.
In Marco Aurélio dos Santos Bernardes, editor, Developments in Heat Transfer, chapter 1, pages 1-20. InTech, Croatia, September 2011a.
Paulo S. André, Margarida Facão, Ana M. Rocha, Paulo Antunes, and André Martins.
Evaluation of the fuse effect propagation in networks infrastructures with different types of fibers.
In Proceedings of Optical Fiber Communication/National Fiber Optic Engineers Conference, March 2010.
Paulo S. André, Fátima Domingues, Margarida Facão, and Ana M. Rocha.
Optical fuse discharge temperature determination employing the CIE color coordinate.
In Conference on Lasers and Electro-Optics Pacific Rim and International Quantum Electronics Conference (CLEOPR/IQEC), pages 1457-1549, Sydney, Australia, August 2011b.
A. Ankiewicz, W. Chen, P. St. J. Russell, M. Taki, and N. Akhmediev.
Velocity of heat dissipative solitons in optical fibers.
Opt. Lett., 33 (19): 2176-2178, September 2008.
P.F.C. Antunes, M. F. F. Domingues, N. J. Alberto, and P. S. André.
Optical fiber micro cavity strain sensors produced by the catastrophic fuse effect.
Photonics Technology Letters, 26 (1): 78-81, January 2014.
R. M. Atkins, P. G. Simpkins, and A. D. Yablon.
Track of a fiber fuse: a Rayleigh instability in optical waveguides.
Opt. Lett., 28 (12): 974-976, June 2003.
I. A. Bufetov and E. M. Dianov.
Optical discharge in optical fibers.
Physics-Uspekhi, 48 (1): 91-94, January 2005.
I. A. Bufetov, E. M. Dianov, and A. A. Frolov.
Optic discharge propagation along a fiber core.
In ICONO/LAT 2005 Technical Digest on CD-ROM, St. Petersburg, Russia, May 2005a.
I. A. Bufetov, E. M. Dianov, A. A. Frolov, V. E. Fortov, and V. P. Efremov.
Dynamics of optical discharge propagation along a fiber.
In ICONO/LAT 2005 Technical Digest on CD-ROM, St. Petersburg, Russia, May 2005b.
I. A. Bufetov, A. A. Frolov, E. M. Dianov, V. E. Fortov, and V. P. Efremov.
Dynamics of fiber fuse propagation.
In Optical Fiber Communication Conference, 2005. Technical Digest. OFC/NFOEC, volume 4, Anaheim, CA, March 2005c.
I. A. Bufetov, A. A. Frolov, V. P. Efremov, M. Ya. Schelev, V. I. Lozovoi, V. E. Fortov, and E. M. Dianov.
Fast optical discharge propagation through optical fibres under kW-range laser radiation.
In Proceedings of the 31st European Conference on Optical Communication, volume 6, pages 39-40, Glasgow, Scotland, September 2005d. IEE's Photonics Professional Network.
I. A. Bufetov, A. A. Frolov, A. V. Shubin, M. E. Likhachev, C. V. Lavrischev, and E. M. Dianov.
Fiber fuse effect under conditions of interference of two modes.
In ICONO/LAT 2007 Technical Digest on CD-ROM, Minsk, Berarusi, May 2007a.
I. A. Bufetov, A. A. Frolov, A. V. Shubin, M. E. Likhachev, C. V. Lavrishchev, and E. M. Dianov.
Fiber fuse effect: New results on the fiber damage structure.
In Proceedings of the 33rd European Conference on Optical Communication, volume 1, pages 79-80, Berlin, Germany, September 2007b. IEE's Photonics Professional Network.
I. A. Bufetov, A. A. Frolov, A. V. Shubin, M. E. Likhachev, S. V. Lavrishchev, and E. M. Dianov.
Propagation of an optical discharge through optical fibres upon interference of modes.
Quantum Electronics, 38 (5): 441-444, May 2008.
E. D. Bumarin and S. I. Yakovlenko.
Temperature distribution in the bright spot of the optical discharge in an optical fiber.
Laser Physics, 16 (8): 1235-1241, August 2006.
D. D. Davis, S. C. Mettler, and D. J. DiGiovani.
Experimental data on the fiber fuse.
In H. E. Bennett, A. H. Guenther, M. R. Kozlowski, B. E. Newnam, and M. J. Soileau, editors, 27th Annual Boulder Damage Symposium: Laser-Induced Damage in Optical Materials: 1995, volume 2714 of SPIE Proceedings, pages 202-210. SPIE, May 1996.
(Boulder, CO, USA, 30 Oct. 1995).
A comparative evaluation of fiber fuse models.
In H. E. Bennett, A. H. Guenther, M. R. Kozlowski, B. E. Newnam, and M. J. Soileau, editors, Laser-Induced Damage in Optical Materials: 1996, volume 2966 of SPIE Proceedings, pages 592-606. SPIE, May 1997.
(Boulder, CO, USA, 7 Oct 1996).
E. Dianov, A. Frolov, I. Bufetov, Y. Chamorovsky, G. Ivanov, and I. Vorobjev.
Fiber fuse effect in microstructured fibers.
In OFC 2003 Technical Digest, volume 2, Atlanta, March 2003.
E. M. Dianov, V. M. Mashinskii, V. A. Myzina, Y. S. Sidorin, A. M. Streltsov, and A. V. Chickolini.
Change of refractive index profile in the process of laser-induced fiber damage.
Sov. Lightwave Commun., 2: 293-299, February 1992.
E. M. Dianov, I. A. Bufetov, A. A. Frolov, V. M. Mashinskii, V. G. Plotnichenko, M. F. Churbanov, and G. E. Snopatin.
Catastrophic destruction of fluoride and chalcogenide optical fibers.
Electron. Letters, 38 (15): 783-784, July 2002a.
E. M. Dianov, I. A. Bufetov, A. A. Frolov, V. G. Plotnichenko, V. M. Mashinskii, M. F. Churbanov, and G. E. Snopatin.
Catastrophic destruction of optical fibres of various composition caused by laser radiation.
Quantum Electron., 32 (6): 476-478, June 2002b.
E. M. Dianov, I. A. Bufetov, and A. A. Frolov.
In OFC 2004 Technical Digest, Los Angels, February 2004a.
Opt. Lett., 29 (16): 1852-1854, August 2004b.
E. M. Dianov, I. A. Bufetov, A. A. Frolov, Y. K. Chamorovsky, G. A. Ivanov, and I. L. Vorobjev.
IEEE Photon. Technol. Lett., 16 (1): 180-181, January 2004c.
E. M. Dianov, A. A. Frolov, I. A. Bufetov, S. L. Semenov, Yu. K. Chamorovskii, G. A. Ivanov, and I. L. Vorob'ev.
The fibre fuse effect in microstructured fibres.
Quantum Electron., 34 (1): 59-61, January 2004d.
E. M. Dianov, I. A. Bufetov, A. E. Rakitin, M. A. Melkumov, A. A. Frolov, V. E. Fortov, V. P. Efremov, and M. I. Kulish.
Temperature of optical discharge under action of laser radiation in silica-based fibres.
In Proceedings of the 31st European Conference on Optical Communication, volume 3, pages 469-470, Glasgow, Scotland, September 2005a. IEE's Photonics Professional Network.
E. M. Dianov, V. E. Fortov, I. A. Bufetov, V. P. Efremov, A. E. Rakitin, M. M. Melkumov, M. I. Kulish, and A. A. Frolov.
Temperature of plasma in silica-based fibers under the action of CW laser radiation.
In International Conference on Strongly Coupled Coulomb Systems Book of Abstracts, pages 25-26, Moscow, Russia, June 2005b.
E. M. Dianov, V. E. Fortov, I. A. Bufetov, V. P. Efremov, A. A. Frolov, M. Ya. Schelev, and V. I. Lozovoi.
Detonation-like mode of the destruction of optical fibers under intense laser radiation.
J. Exp. Theo. Phys. Lett., 83 (2): 75-78, March 2006a.
E. M. Dianov, V. E. Fortov, I. A. Bufetov, V. P. Efremov, A. E. Rakitin, M. A. Melkumov, M. I. Kulish, and A. A. Frolov.
High-speed photography, spectra, and temperature of optical discharge in silica-based fibers.
IEEE Photon. Technol. Lett., 18 (6): 752-754, March 2006b.
F. Domingues, A. R. Frias, P. Antunes, A. O. P. Sousa, R. A. S. Ferreira, , and P. S. André.
Observation of fuse effect discharge zone nonlinear velocity regime in erbium-doped fibres.
Electron. Lett., 48 (20): 1295-1296, September 2012a.
Fátima Domingues, Ana Rocha, Paulo Antunes, Ana R. Frias, Rute A. S. Ferreira, and Paulo S. André.
Evaluation of the fuse effect propagation velocity in bend loss insensitive fibers.
In Technical Digest - 17th OptoElectronics and Communications Conference, OECC2012, pages 799-800, July 2012b.
Fátima Domingues, Ana Rocha, Ana R. Frias, and Paulo S. André.
Evaluation of the temperature increase on the fiber fuse effect end point.
In the 14th International Conference on Transparent Optical Networks (ICTON 2012), Coventry, England, July 2012c.
Fátima Domingues, Paulo Antunes, Nelia Alberto, and Paulo S. André.
Refractive index sensor based on optical fiber void cavities produced by the catastrophic fuse effect.
In Advanced Photonics 2013, OSA Technical Digest, July 2013.
M. Fátima Domingues, Paulo Antunes, Nélia Alberto, Rita Frias, Rute A. S. Ferreira, and Paulo André.
Optical strain sensor based on fpi micro-cavities produced by the fiber fuse effect.
In J. M. M. Serrano, M. López-Amo, J. M. López-Higuera, and J. D. C. Jones, editors, 23rd International Conference on Optical Fiber Sensors, volume 9157 of SPIE Proceedings, page 91571Q. SPIE, June 2014.
A. Yu. Dovzhenko, E. N. Rumanov, and O. E. Yachmeneva.
Effect of slight damage on the action of an optical fiber.
Dokl. Phys., 57 (10): 383-386, October 2012.
(Originally published in Russian, Doklady Akademii Nauk, 2012, Vol. 446, No. 5, pp. 510513).
T. J. Driscoll, J. M. Calo, and N. M. Lawandy.
Opt. Lett., 16 (13): 1046-1048, July 1991.
D. A. Dvoretskiy, V. F. Hopin, A. N. Gur'yanov, L. K. Denisov, L. D. Ishakova, and I. A. Bufetov.
Optical losses in silica based fibers within the temperature range from 300 to 1500 K.
Science and Education: electronic scientific-technical journal, (5), May 2013.
M. Facão, A. M. Rocha, and P. S. André.
Traveling solutions of the fuse effect in optical fibers.
Journal of Lightwave Technology, 29 (1): 109-114, January 2011.
A. A. Frolov, I. A. Bufetov, and E. M. Dianov.
Propagation of the optical discharge through the fibers with thin silica cladding.
A. A. Frolov, E. M. Dianov, and I. A. Bufetov.
Destruction of silica fiber cladding by the optical discharge propagation.
R. I. Golyatina and S. I. Yakovlenko.
On the mechanism of optical discharge stop in the tapered region of fibre cladding.
Quantum Electron., 35 (5): 422-424, May 2005.
R. I. Golyatina, A. N. Tkachev, and S. I. Yakovlenko.
Calculation of the motion of the laser radiation absorption thermal wave in a fiberguide.
Bulletin of the Lebedev Physics Institute, (9): 22-29, September 2004a.
(Kratk. Soobshch. Fiz., 9, pp.26-33, 2004, in Russian).
Calculation of velocity and threshold for a thermal wave of laser radiation absorption in a fiber optic waveguide based on the two-dimensional nonstationary heat conduction equation.
Laser Physics, 14 (11): 1429-1433, November 2004b.
2D calculation of a fiber fuse propagation.
Analysis of a heat wave induced by laser radiation absorption in an optical fiber on the basis of a 2D nonstationary heat conduction equation.
Tech. Phys., 50 (2): 232-236, February 2005b.
(Zh. Tech. Fiz. 75 (2) 94 (2005)).
V. I. Gorbachenko, A. Yu. Dovzhenko, A. G. Merzhanov, É. N. Rumanov, V. E. Fortov, and O. E. Yachmeneva.
Propagation limits for a slow wave of optical breakdown in a fiber light guide.
Dokl. Phys., 55 (8): 384-387, August 2010.
(Originally published in Russian, Doklady Akademii Nauk, 2010, Vol. 433, No. 5, pp. 618621).
Woosung Ha, Yoonseob Jeong, and Kyunghwan Oh.
Fiber fuse effect in hollow optical fibers.
Opt. Lett., 36 (9): 1536-1538, May 2011.
D. P. Hand and T. A. Birks.
Single-mode tapers as 'fibre fuse' damage circuit-breakers.
Electron. Lett., 25 (1): 33-34, January 1989.
D. P. Hand and P. St. J. Russell.
Soliton-like thermal shock-waves in optical fibers: origin of periodic damage tracks.
In Eur. Conf. Optical Communications, pages 111-114, September 1988a.
(Brighton, UK, 11-15 Sep 1988).
Solitary thermal shock waves and optical damage in optical fibers: the fiber fuse.
Opt. Lett., 13 (9): 767-769, September 1988b.
D. P. Hand, J. E. Townsend, and P. St. J. Russell.
Optical damage in fibres: the fibre fuse.
In Digest of Conf. on Lasers and Electro-Optics, April 1988.
N. Hanzawa, K. Kurokawa, K. Tsujikawa, T. Matsui, and S. Tomita.
Suppression of fiber fuse propagation in photonic crystal fiber (PCF) and hole assisted fiber.
In Technical Digest of Microoptics Conference, page M7, October 2009.
Nobutomo Hanzawa, Kenji Kurokawa, Kyozo Tsujikawa, Takashi Matsui, Kazuhide Nakajima, Shigeru Tomita, and Makoto Tsubokawa.
Suppression of fiber fuse propagation in hole assisted fiber and photonic crystal fiber.
J. Lightwave Technology, 28 (15): 2115-2120, July 2010a.
Nobutomo Hanzawa, Kenji Kurokawa, Kyozo Tsujikawa, Katsuhiro Takenaga, Shoji Tanigawa, Shoichiro Matsuo, and Shigeru Tomita.
New propagation mode of fiber fuse with a long-period damage track in hole-assisted fiber (HAF).
In Proceedings of Optical Fiber Communication/National Fiber Optic Engineers Conference, March 2010b.
Observation of a propagation mode of a fiber fuse with a long-period damage track in hole-assisted fiber.
Optics Letters, 35 (12): 2004-2006, June 2010c.
Nobutomo Hanzawa, Kenji Kurokawa, Kyozo Tsujikawa, and Shigeru Tomita.
Dynamics of new propagation mode of fiber fuse in hole-assisted fiber (HAF).
In Technical Digest - 15th OptoElectronics and Communications Conference, OECC2010, pages 172-173, July 2010d.
Self-propelled self-focusing damage in optical fibres.
In F. J. Duarte, editor, Lasers '87; Proc. the 10th Int. Conf. Lasers and Applications, pages 859-866, McLean, VA, January 1988. STS Press.
(Lake Tahoe, Nevada, USA, Dec. 7-11, 1987).
High average power effects in optical fibers and devices.
In H. G. Limberger and M. J. Matthewson, editors, Reliability of Optical Fiber Components, Devices, Systems, and Networks, volume 4940 of SPIE Proceedings, pages 108-117. SPIE, April 2003.
(Brugge, Belgium, 28 Oct. 2002).
Fiber fuse - from a curious effect to a critical issue.
In Proceedings of the 38th European Conference on Optical Communication, September 2012a.
Fiber fuse - from a curious effect to a critical issue: A 25th year retrospective.
Optics Express, 21 (5): 6422-6441, March 2013a.
R. Kashyap and K. J. Blow.
Spectacular demonstration of catastrophic failure in long lengths of optical fibre via self-propelled self-focusing.
Eighth National Quantum Electronics Conference, Post Deadline (Poster) Session PD7, September 1987.
Observation of catastrophic self-propelled self-focusing in optical fibres.
Electron. Lett., 24 (1): 47-49, January 1988.
R. Kashyap, A. Sayles, and G. F. Cornwell.
Heat flow modeling and visualization of catastrophic selfpropagating damage in singlemode optical fibers at low powers.
In H. E. Bennett, A. H. Guenther, M. R. Kozlowski, B. E. Newnam, and M. J. Soileau, editors, Laser-Induced Damage in Optical Materials: 1996, volume 2966 of SPIE Proceedings, pages 586-591. SPIE, May 1997.
History and progress of the fibre fuse.
In Technical Digest - 17th OptoElectronics and Communications Conference, OECC2012, pages 807-808, July 2012b.
When a friend becomes a foe: The optical fiber fuse.
In 3rd Workshop on Specialty Optical Fibers and their Applications, August 2013b.
Takahiro Kinoshita, Norihiko Sato, and Makoto Yamada.
Detection and termination system for optical fiber fuse.
In OptoElectronics and Communications Conf. held jointly with 2013 Int. Conf. on Photonics in Switching (OECC/PS), July 2013.
Optical fiber for high-power optical communication.
Crystals, 2 (4): 1382-1392, September 2012.
Techniques to detect and stop fiber fuses.
In Proceedings of Optical Fiber Communication/National Fiber Optic Engineers Conference, March 2014.
Kenji Kurokawa and Nobumoto Hanzawa.
Suppression of fiber fuse propagation and its break in compact fiber fuse terminator.
Kenji Kurokawa and Nobutomo Hanzawa.
Fiber fuse propagation and its suppression in hole-assisted fibers.
IEICE Transactions on Communications, E94.B (2): 384-391, February 2011.
Kenji Kurokawa, Nobutomo Hanzawa, Kyozo Tsujikawa, and Shigeru Tomita.
Power dependence of fiber fuse propagation with a long-period damage track in hole-assisted fiber.
IEICE Electronics Express, 8 (11): 802-807, June 2011.
Meredith M. Lee, Jeffrey M. Roth, Todd G. Ulmer, and Colm V. Cryan.
The fiber fuse phenomenon in polarization-maintaining fibers at 1.55 m.
In Proc. of the Conference on Lasers and Electro-Optics (CLEO), May 2006.
Guei-Ru Lin, Mohamad Diaa Baiad, Mathieu Gagne, Wen-Fung Liu, and R. Kashyap.
Harnessing the fiber fuse for sensing applications.
Optics Express, 22 (8): 8962-8969, April 2014a.
Guei-Ru Lin, Mohamad Diaa Baiad, Mathieu Gagne, Wen-Fung Liu, and Raman Kashyap.
A novel refractive index sensor based on an induced micro-structure fiber.
In J. M. M. Serrano, M. López-Amo, J. M. López-Higuera, and J. D. C. Jones, editors, 23rd International Conference on Optical Fiber Sensors, volume 9157 of SPIE Proceedings, page 915773. SPIE, June 2014b.
Y. Mizuno, N. Hayashi, H Tanaka, and K. Nakamura.
Spiral propagation of polymer optical fiber fuse accompanied by spontaneous burst and its real-time monitoring using brillouin scattering.
Photonics Journal, IEEE, 6 (3): 6600307, June 2014a.
Yosuke Mizuno, Neisei Hayashi, Hiroki Tanaka, Kentaro Nakamura, and S. Todoroki.
Observation of polymer optical fiber fuse.
Appl. Phys. Lett., 104 (4): 043302, January 2014b.
First observation of fiber fuse phenomenon in polymer optical fibers.
In J. M. M. Serrano, M. López-Amo, J. M. López-Higuera, and J. D. C. Jones, editors, 23rd International Conference on Optical Fiber Sensors, volume 9157 of SPIE Proceedings, page 9157AI. SPIE, June 2014c.
Propagation mechanism of polymer optical fiber fuse.
Scientific Reports, 4: 4800, April 2014d.
N. Nishimura, K. Seo, M. Shiino, and R. Yuguchi.
Study of high-power endurance characteristics in optical fiber link.
In Technical Digest of Optical Amplifiers and Their Applications, pages 193-195, July 2003.
R. M. Percival, E. S. R. Sikora, and R. Wyatt.
Catastrophic damage and accelerated ageing in bent fibres caused by high optical powers.
Electron. Lett., 36 (5): 414-416, March 2000.
A. M. Rocha, M. Facão, A. Martins, and P. S. André.
Simulation of fiber fuse effect propagation.
In International Conf. on Transparent Networks - Mediterranean Winter, 2009, Angers, France, December 2009.
A. M. Rocha, P. Antunes, F. Domingues, M. Facão, and P. S. André.
Configuration for detecting the fiber fuse propagation using a FBG sensor.
In 12th International Conf. on Transparent Networks, Munich, Germany, June 2010a.
A. M. Rocha, M. Facão, and P. S. André.
Study of fiber fuse effect on different types of single mode optical fibers.
In Dave Faulkner, editor, NOC/OC&I 2010 Proceedings : 15th European Conference on Networks and Optical Communications and 5th Conference on Optical Cabling and Infrastructure (ISBN: 9789729341939), pages 71-75, Faro-Algarve, Portugal, June 2010b. Universidade do Algarve.
A. M. Rocha, P. S. André, M. F. F. Domingues, and M. Facão.
Reflected light due to the fiber fuse propagation.
In International conference on computer as a tool - Eurocon 2011 and 8 th conference of Telecommunications, Lisbon, Portugal, April 2011a.
A. M. Rocha, P. F. C. Antunes, M. F. F. Domingues, M. Facão, and P. S. André.
Detection of fiber fuse effect using FBG sensors.
IEEE Sensors Journal, 11 (6): 1390 -1394, June 2011b.
A. M. Rocha, G. Fernandes, F. Domingues, M. Niehus, M. Facão, and P. S. André.
Halting the fuse discharge propagation using optical fiber microwires.
Optics Express, 20 (19): 21083-21088, September 2012.
Ana Rocha, Gil Fernandes, F. Domingues, Armando Pinto, Margarida Facão, and Paulo André.
Fiber fuse effect propagation break using optical fiber taper.
In Technical Digest - 16th OptoElectronics and Communications Conference, OECC2011, pages 593-594, July 2011c.
Ana M. Rocha, Fátima Domingues, Margarida Facão, and Paulo S. André.
Threshold power of fiber fuse effect for different types of optical fiber.
In the 13th International Conference on Transparent Optical Networks (ICTON 2011), pages 1457-1549, Stockholm, Sweden, June 2011d.
Edson H. Sekiya, Kazuya Saito, Yao Bing, Akira Ogura, and Kazumasa Ohsono.
Fiber fuse in multi core fibers.
電子情報通信学会技術研究報告 OFT 光ファイバ応用技術, 112 (194): 19-22, August 2012.
K. Seo, N. Nishimura, M. Shiino, R. Yuguchi, and H. Sasaki.
Evaluation of high-power endurance in optical fiber links.
Furukawa Review, (24): 17-22, July 2003a.
Examination of threshold power for high-power problems in optical fiber.
In Proc. Int. Laser Safety Conf., pages 298-302, Jacksonville, FL, March 2003b.
Evaluation of high-temperature absorption coefficients of ionized gas plasmas in optical fibers.
IEEE Photon. Technol. Lett., 22 (3): 134-136, February 2010.
Y. Shuto, S. Yanagi, S. Asakawa, M. Kobayashi, and R. Nagase.
Simulation of fiber fuse phenomenon in single-mode optical fibers.
J. Lightwave Tech., 21 (11): 2511-2517, November 2003.
Fiber fuse phenomenon in step-index single-mode optical fibers.
IEEE J. Quantum Electronics, 40 (8): 1113-1121, August 2004a.
Evaluation of high-temperature absorption coefficients of optical fibers.
IEEE Photon. Technol. Lett., 16 (4): 1008-1010, April 2004b.
Fiber fuse generation in single-mode fiber-optic connectors.
IEEE Photon. Techol. Lett., 16 (1): 174-176, January 2004c.
Fiber fuse phenomenon in triangular-profile single-mode optical fibers.
J. Lightwave Technol., 24 (2): 846-852, February 2006.
Heat conduction modeling of fiber fuse in single-mode optical fiber.
J. Photonics, 2014: 645207, February 2014.
H. Takara, H. Masuda, H. Kanbara, Y. Abe, Y. Miyamoto, R. Nagase, T. Morioka, S. Matsuoka, M. Shimizu, and K. Hagimoto.
Evaluation of fiber fuse characteristics of hole-assisted fiber for high power optical transmission systems.
In Proceedings of the 35th European Conference on Optical Communication, page 312, September 2009.
K. Takenaga, S. Omori, R. Goto, S. Tanigawa, S. Matsuo, and K. Himeno.
Evaluation of high-power endurance of bend-insensitive fibers.
In Proceedings of Optical Fiber Communication/National Fiber Optic Engineers Conference, February 2008.
A. N. Tkachev and S. I. Yakovlenko.
Calculation of the velocity and threshold of a thermal absorption wave of laser radiation in an optical fibre.
Quantum Electron., 34 (8): 761-764, August 2004.
In-situ observation of fiber-fuse propagation.
In Proc. 30th European Conf. Optical Communication Post-deadline papers, pages 32-33, Stockholm, Sweden, September 2004. Kista Photonics Research Center.
Jpn. J. Appl. Phys., 44 (6A): 4022-4024, June 2005a.
Origin of periodic void formation during fiber fuse.
Optics Express, 13 (17): 6381-6389, August 2005b.
Transient propagation mode of fiber fuse leaving no voids.
Optics Express, 13 (23): 9248-9256, November 2005c.
Animation of fiber fuse damage, demonstrating periodic void formation.
Opt. Lett., 30 (19): 2551-2553, October 2005d.
Ultrahigh-speed videography of fiber fuse propagation: a tool for studying void formation.
In International Conference on Lasers, Applications, and Technologies 2005: Laser-Assisted Micro- and Nanotechnologies, volume 6161 of SPIE Proceedings, pages 61610L-1-8. SPIE, February 2006a.
(St. Petersburg, Russia, 15 May 2005, LSuH1).
In-situ observation of fiber-fuse ignition.
In V. I. Konov, V. Y. Panchenko, K. Sugioka, and V. P. Veiko, editors, International Conference on Lasers, Applications, and Technologies 2005: Laser-Assisted Micro- and Nanotechnologies, volume 6161 of SPIE Proceedings, pages 61610N-1-4. SPIE, February 2006b.
(St. Petersburg, Russia, 14 May 2005, LSK3).
In situ observation of modulated light emission of fiber fuse synchronized with void train over hetero-core splice point.
PLoS ONE, 3 (9): e3276, September 2008.
Light and voids of fiber fuse: precise comparison of in situ image and fused fibers.
In 19th International Laser Physics Workshop: Book of Abstracts, page 463, Foz do Iguaçu, Brazil, July 2010.
Threshold power reduction of fiber fuse propagation through a white tight-buffered single-mode optical fiber.
IEICE Electronics Express, 8 (23): 1978-1982, December 2011.
In Yasin Moh, Sulaiman W. Harun, and Hamzah Arof, editors, Selected Topics on Optical Fiber Technology, chapter 20, pages 551-570. InTech, Croatia, February 2012a.
Partially self-pumped fiber fuse propagation through a white tight-buffered single-mode optical fiber.
In Optical Fiber Communication Conference, OSA Technical Digest. Optical Society of America, March 2012b.
Fiber fuse propagation modes in typical single-mode fibers.
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