Educational Background:

Bachelor, Shandong University, China

Master, Fudan University, China

Doctor, University of Central Florida, US

Personal Homepage (EN):

http://gtaolab.com/English/Home.html

Publications:

Journals

69) L. Gong, F. Zhang, X. Peng, F. Scarpa, Z. Huang, G. Tao, H. Liu, H. Zhou, H. Zhou, "Improving the damping properties of carbon fiber reinforced polymer composites by interfacial sliding of oriented multilayer graphene oxide," Compos. Sci. Technol. 109309 (2022).

68) M. Chen, W. Xiao, M. Li, Y. Hao, L. Hu, G. Tao*, "A multi-feature and time-aware-based stress evaluation mechanism for mental status adjustment," ACM Trans. Multimedia Comput. Commun. Appl. 18, 1-18 (2022). [*Corresponding author]

67) M. Chen, K. Shen, R. Wang, Y. Miao, Y. Jiang, K. Hwang, Y. Hao, G. Tao, L. Hu, Z. Liu, "Negative Information Measurement at AI Edge: A New Perspective for Mental Health Monitoring," ACM Trans. Internet Technol. 22(3), 1-16 (2022).

66) M. Chen, R. Wang, R. Wang, Y. Zhou, Z. He, X. Liu, M. He, J. Wang, C. Huang, H. Zhou, Pv Hong, C. Hou, N. Zhou, D. Zhang, G. Tao*, "Intelligent fabric space empowered digital medical education," National Science Open in press (2021). [*Corresponding author]

65) 曾少宁，胡佳雨，张曼妮，向远卓，吴嘉威，苏敏钰，张雨琪，沈梦，洪平，黄朝林，陈敏，周宁，侯冲，周华民，张定宇^*，陶光明*, “面向个人热管理的降温纺织品,” 科学通报，出版中(2021). Invited paper [*Corresponding author]

64) F. Meng, X. Zhao, J. Ding, Y. Niu, X. Zhang, L. Yang, X. Wang, S. Lou, X. Sheng, G. Tao*, S. Liang*, “Discovering extremely low confinement-loss anti-resonant fibers via swarm intelligence,” Opt. Express 29 (22), 35544-35555 (2021). [*Corresponding author]

63) R. Wang, Z. Du, Z. Xia, J. Liu, P. Li, Z. Wu, Y. Yue, Y. Xiang, J. Meng, D. Liu, W. Xu*, X. Tao*, G. Tao*, B. Su*, “Magnetic clothing generator for high-performance transduction from biomechanical energy to electricity,” Adv. Funct. Mater.2107682 (2021). [*Corresponding author]

62) R. Liu, J. Li, J. Duan*, B. Yu, W. Xie, B. Qi, H. Wang, X. Zhuang, S. Liu, P. Liu, G. Tao, M. Xu, J. Zhou, “High-efficiency solar heat storage enabled by adaptive radiation management,” Cell Reports Physical Science2 (8) 100533 (2021).

61) J. Ding, F. Meng, X. Zhao, L. Yang, X. Wang, S. Lou, X. Sheng, R. Buczyński, G. Tao*, and S. Liang*, “Refractive-index guiding single crystal optical fiber with air–solid cladding,” Opt. Mater. Express 11(9), 2994-3006 (2021). [*Corresponding author]

60) F. Meng, X. Zhao, J. Ding, Y. Niu, X. Zhang, M. Smietana, R. Buczyński, B. Lin, G. Tao, L. Yang, X. Wang, S. Lou, X. Sheng, S. Liang, “Use of machine learning to efficiently predict the confinement loss in anti-resonant hollow-core fiber,” Opt. Lett. 46(6), 1454-1457 (2021).

59) S. Zeng, S. Pian, M. Su, X. Liu, M. Wu, M. Chen, Z. Wang, Y. Xiang, J. Wu, M. Zhang, Q. Cen, Y. Tang, X. Zhou, Z. Huang, R. Wang, A. Tunuhe, X. Ma, Z. Xia, M. Tian, L. Yang, Q Yang, M. Chen, J. Zhou, H. Zhou, X. Li, Y. Ma*, G. Tao*, “Hierarchical-morphology metafabric for scalable passive daytime radiative cooling,” Science 373(6555), 692-696 (2021). [*Corresponding author]

58) Y. Ma, J. Ouyang, T. Raza, P. Li, A. Jian, Z. Li, H. Liu, M. Chen, X. Zhang, L. Qu*, M Tian*, G. Tao*, “Flexible all-textile dual tactile-tension sensors for monitoring athletic motion during Taekwondo,” Nano Energy 85, 105941 (2021). [*Corresponding author]

57) M. Chen, W. Xiao, Y. Ma, Y. Zhang, L. Hu*, G. Tao*, “Cognitive wearable robotics for autism perception enhancement,” ACM Trans. Internet Technol. 21(4), 1-16 (2021). [*Corresponding author]

56) K. Wang, C. Fu, R. Wang, G. Tao*, Z Xia*, ”High-resilience cotton base yarn for anti-wrinkle and durable heat-insulation fabric,” Compos. B. Eng. 108663(2021)  [*Corresponding author]

55) K. He, Y. Hou, C. Yi, N. Li, F. Sui, B. Yang, G. Gu, W. Li, Z. Wang, Y. Li, G. Tao*, L. Wei*, C. Yang*, M. Chen*, “High-performance zero-standby-power-consumption-under-bending pressure sensors for artificial reflex arc.” Nano Energy 104743(2020). [*Corresponding author]

54) S.Tian, F. Sui, K. He, G. Cheng, Y. Ge, D. Ning, Z. Wang, Z. Wang, G. Tao, Z. Wang, B. Du, L. Wei, W. Li, C. Yang, M. Chen, “Co-axial silicon/perovskite heterojunction arrays for high-performance direct-conversion pixelated X-ray detectors,” Nano Energy 105335 (2020).

53) M. Du, L. Huang, J. Zheng, Y. Xi, Y. Dai, W. Zhang, C. Ren, W. Yan, G. Tao, J. Qiu, K-F. So, S. Zhou, “Functional probes: Flexible fibre probe for efficient neural stimulation and detection,” Adv. Sci. 7, 2070086 (2020). Back-cover story

52) L. Yang, H. Liu, S. Ding, J. Wu, Y. Zhang, Z. Wang*, L. Wei*, M. Tian*, G. Tao*, “Superabsorbent textile towards comfortable disposable medical protective clothing,” Adv. Fiber Mater. 2, 140–149 (2020). [*Corresponding author]

51) H. Zhao, R. Hu, X. Zhang, X. Qi, Q. Fan, M. Tian*, G. Tao*, L. Qu*, “Soft bimorph actuator with real-time multiplexing motion perception,” Nano Energy 104926 (2020). [*Corresponding author]

50) R. Hu*, J. Song, Y. Liu, W. Xi, Y. Zhao, X. Yu, Q. Cheng, G. Tao*, X Luo*, “Machine learning-optimized tamm tmitter for high-performance thermophotovoltaic system with detailed balance analysis,” Nano Energy 72,104687 (2020). [*Corresponding author]

49) K.He, Y. Hou, C. Yi, N. Li, F. Sui, B. Yang, G. Gu, W. Li, Z. Wang, G. Tao*, L. Wei*, C. Yang*, M. Chen*, “Tunable pressure sensors with ultrahigh sensitivity and wide linear response for artificial reflex arc,” Nano Energy 73, 104743 (2020).[*Corresponding author]

48) Y. Lian, H. Yu*, M. Wang, X. Yang, Z. Li, F. Yang, Y. Wang, H. Tai, Y. Liao, J. Wu, X. Wang*, Y. Jiang, and G. Tao*, “Multifunctional wearable e-textile via integrated nano wire coated fabrics.” J. Mater. Chem. C 8, 8399-8409 (2020). [*Corresponding author] Back-cover story

47) W. Yan, C. Dong, Y. X, S. Jiang, A. Leber, G. Loke, W. Xu, C. Hou, S. Zhou, M. Chen, R. Hu, P. Shum, L. Wei, X. Jia, F. Sorin, X. Tao, G. Tao*, “Thermally drawn advanced functional fibers: New frontier of flexible electronics,” Mater. Today 35, 168-194 (2020). [*Corresponding author] ESI highly-cited paper

46) M. Chen, Y. Jiang, N. Guizani, J. Zhou, G. Tao*, J. Yin and K. Hwang, “Living with I-Fabric: Smart living powered by sensing fabric and deep analytics,” IEEE Network 34, 156-163 (2020). [*Corresponding author]

45) Z. Du, J. Ai, X. Zhang, Z. Ma, D. Chen, G. Tao, B. Su, “Stretchable magnetoelectric fibers for self-powered tactile sensing,” Applied Mater. Today 20, 100623, (2020).

44) J. Wu, R. Hu, S. Zeng, W. Xi, S. Huang, J. Deng, and G. Tao*, “Flexible and robust biomaterial microstructured coloured textiles for personal thermoregulation,” ACS Appl. Mater. Interfaces 12, 19015-19022 (2020). [*Corresponding author]

[“New textile could keep you cool in the heat, warm in the cold,“ ACS News Service Weekly Press Pac, April 15, 2020, featured at acs.org, Phys.org, eurekalert.org; Ben Coxworth, “Phase-change fabric both warms and cools its wearer,” New Atlas, April 15, 2020, featured at newatlas.com; “Smart fabric adapts to weather conditions to warm or cool the wearer,” The Amed Post, April 17, 2020, featured at amedpost.com]

43) R. Hu, S. Shin, Y. Liu, S. Huang, X. Ren, W. Shu, J. Cheng, G. Tao, W. Xu, R. Chen, X. Luo, “Emerging materials and strategies for personal thermal management,” Adv. Energy Mater. 10 (17), 1903921(2020).

42) G. Tao†, Shi Chen†, S. J. Pandey, F. A. Tan, H. Ebendorff-Heidepriem, M. Molinari, A. F. Abouraddy, and R. M. Gaume, “A carbon-nanofiber glass composite with high electrical conductivity,” I. J. Appl. Glass Science 11, 590-600 (2020). [†Co-first author]

41) B.Xu, S. Ma, Y. Xiang, J. Zhang, M. Zhu, L. Wei*, G. Tao* and D. Deng*, “In-fiber structured particles and filament arrays froom the perspective of fluid instabilities,” Adv. Fiber Mater. 2, 1–12(2020). [*Corresponding author] Front-cover story

40) J. Yang. J. Zhou, G. Tao*, M. Alrashoud, K. N. Al Mutib and Al-Hammadi, “Wearable 3.0: From smart clothing to wearable affective robot,” IEEE Network 33, 8-14 (2019). [*Corresponding author]

39) M Zhu, T Kikutani, T Liu, S Ramakrishna, G Tao, “Fiber changes our life,” Adv. Fiber Mater. 1, 1–2(2019).

38) H Lang, Y Peng, G Shao, K Zou, G Tao, “Dual control of the nanofriction of graphene,” J. Mater. Chem. C 7, 6041-6051 (2019).

37) M. Chen, J. Zhou, G. Tao, J. Yang, and L. Hu, “Wearable affective robot,” IEEE Access 6, 64766-64776 (2018).

36) M. Du, S. Ye, J. Tang, S. Lv, J. Chen, J. Orava, G. Tao, P. Lan, J. Hao, Z. Yang, J. Qiu, and S. Zhou, “Scalable in-Fiber manufacture of functional composite particles,” ACS Nano 12, 11130-11138 (2018).

35) S. Shabahang, F. A. Tan, J. D. Perlstein, G. Tao, O. Alvarez, F. Chenard, K. L. Schepler, and A. F. Abouraddy, “Robust multimaterial chalcogenide fibers produced by a hybrid fiber-fabrication process,” Opt. Mater. Express 7, 2336-2345 (2017).

34) G. Tao, J. J. Kaufman, S. Shabahang, R. R. Naraghi, S. V. Sukhov, J. D. Joannopoulos, Y. Fink, A. Dogariu, and A. F. Abouraddy, “Digital design of multimaterial photonic particles,” Proc. Natl. Acad. Sci. USA 113, 6839-6844 (2016).

33) S. Shabahang, G. Tao, J. J. Kaufman, Y. Qiao, L. Wei, T. Bouchenot, A. P. Gordon, Y. Fink, Y. Bai, R. S. Hoy, and A. F. Abouraddy, “Controlled fragmentation of multimaterial fibres and films via polymer cold-drawing,” Nature 534, 529-533 (2016).

[Highlights: MIT (“New method snips complex fibers into uniform particles”), ScienceDaily, Phy.org, today.UCF, materialstoday, compositesworld, materialsforengineering, Bioportfolio, healthmedicinet, nanowerk, sciencenewsline, eurekalert!, nanotech-now, ECN, ecnmag, spectrum.ieee.org, materialsgate, chemeurope, Noodls, etc]

32) C. Jiang, X. Wang, M. Zhu, H. Xu, Q. Nie, S. Dai, G. Tao, X. Shen, C. Cheng, Q. Zhu, F. Liao, P. Zhang, P. Zhang, Z. Liu, X. Zhang, “Preparation of chalcogenide glass fiber using an improved extrusion method,” Opt. Eng. 55, 056114 (2016).

31) B. Ye, S. Dai, R. Wang, G. Tao, P. Zhang, X. Wang, X. Shen, “Influence of the selenium content on thermos-mechanical and optical properties of Ge-Ga-Sb-S chalcogenide glass,” Infrared Phys. & Tech. 77, 21-26 (2016).

30) W. Guo, B. Zhang, C. Zhai, S. Qi, Y. YU, A. Yang, L. Li, Z. Yang, R. Wang, D. Tang, G. Tao, B. Luther-Davies, “Fabrication and application of small core chalcogenide glass fibers in nonlinear optics,” J. Inorganic Mater. in Chinese, 31, 180-184 (2016).

29) C. Zhai, B. Zhang, S. Qi, W. Guo, Z. Yang, A. Yang, M. Zhang, Y. Yang, Y. Yu, R. Wang, G. Tao, D. Tang, and B. Luther-Davies, “Fabrication and properties of flexible chalcogenide fiber image bundles,” Acta Opt. Sin. in Chinese, 35, 0806005 (2015).

28) B. Zhang, C. Zhai, S. Qi, W. Guo, Z. Yang, A. Yang, X. Gai, Y. Yu, R. Wang, D. Tang, G. Tao, and B. Luther-Davies, “High resolution chalcogenide fiber bundles for infrared imaging,” Opt. Lett., 40, 4384-4387 (2015).

27) Y. Sun, S. Dai, P. Zhang, X. Wang, Y. Xu, Z. Liu, F. Chen, Y. Wu, Y. Zhang, R. Wang, and G. Tao, “Fabrication and characterization of multimaterial chalcogenide glass fiber tapers with high numerical apertures,” Opt. Express, 23, 23472-23483 (2015).

26) C. Wang, S. Dai, P. Zhang, B. Zhang, X. Wang, X. Shen, J. Hou, R. Wang, and G. Tao, “Research progress of infrared supercontinuum generation in chalcogenide glass fibers,” Laser & Optoelectronics Progress in Chinese, 52, 030001 (2015).

25) L. Chen, F. Chen, S. Dai, G. Tao, L. Yan, X. Shen, H. Ma, X. Zhang, and Y. Xu, “Third-order nonlinearity in Ge-Sb-Se glasses at mid-infrared wavelengths,” Mater. Res. Bull., 70, 204-208 (2015).

24) B. Zhang, W. Guo, Y. Yu, C. Zhai, S. Qi, A. Yang, L. Li, Z. Yang, R. Wang, D. Tang, G. Tao, and B. Luther-Davies, “Low loss, high NA chalcogenide glass fibers for broadband mid-infrared supercontinuum generation,” J. Am. Ceram. Soc. 98, 1389–1392 (2015).

23) M. Zhu, X. Wang, Z. Pan, C. Cheng, Q. Zhu, C. Jiang, Q. Nie, P. Zhang, Y. Wu, S. Dai, T. Xu, G. Tao, and X. Zhang, “Fabrication of an IR hollow-core Bragg fiber based on chalcogenide glass extrusion,” Appl. Phys. A 119, 455-460 (2015).

22) C. Jiang, C. Cheng, Q. Zhu, X. Wang, Q. Nie, S. Dai, G. Tao, M. Zhu, F. Liao, P. Zhang, X. Shen, T. Xu, P. Zhang, Z. Liu, and X. Zhang, “Fabrication and characterization of Ge-Sb-Se-I glasses and fibers,” Appl. Phys. A 120, 127-135 (2015).

21) P. Yang, P. Zhang, S. Dai, Y. Wu, X. Wang, G. Tao, and Q. Nie, “Tapered chalcogenide–tellurite hybrid microstructured fiber for mid-infrared supercontinuum generation, “ J. Mod. Opt. 62, 729-737 (2015).

20) M. Zhu, X. Wang, C. Jiang, H. Xu, Q. Nie, P. Zhang, S. Dai, X. Shen, T. Xu, G. Tao, and, X. Zhang, “Freely adjusted properties in Ge-S based chalcogenide glasses with iodine incorporation,” Infrared Phys. & Tech. 69, 118-122 (2015).

19) G. Tao, H. Ebendorff-Heidepriem, A. M. Stolyarov, S. Danto, J. V. Badding, Y. Fink, J. Ballato, and A. F. Abouraddy, “Infrared fibers,”Adv. Opt. Photon. 7, 379-458, (2015). Invited Review paper. [Top Downloads from Jun. 2015 to Feb. 2016] ESI highly-cited paper

18) G. Tao, S. Shabahang, S. Dai, and A. F. Abouraddy, “Multimaterial disc-to-fiber approach efficiently produce robust infrared fibers,” Opt. Mater. Express 4, 2143–2149 (2014).

17) H. Xu, X. Wang, Q. Nie, M. Zhu, C. Jiang, F. Liao, P. Zhang, P. Zhang, S. Dai, T. Xu, and G. Tao, “Fabrication and properties of chalcogenide optical fiber based on a novel extrusion method,” J. Optoelectronics ● Laser  in Chinese, 25, 1109-1114 (2014).

16) G. Tao, S. Shabahang, H. Ren, F. Khalizadeh-Rezaie, R. E. Peale, Z. Yang, X. Wang, and A. F. Abouraddy, “Robust multimaterial tellurium-based chalcogenide glass fibers for mid-wave and long-wave infrared transmission,” Opt. Lett. 39, 4009-4012 (2014).

15) H. Ren, G. Tao*, A. Yang, H. Guo, G. Yang, Y. Xu, X. Wang, and Z. Yang*, “Recent progress of Tellurium-based chalcogenide long-wave infrared transmitting fibers,” *corresponding author, Infrared in Chinese 35, 7–12 (2014).

14) H. Xu, Y. He, X. Wang, Q. Nie, P. Zhang, T. Xu, S. Dai, X. Zhang, and G. Tao, “Preparation of low-loss Ge₁₅Ga₁₀Te₇₅ chalcogenide glass for Far-IR optics applications,” Infrared Phys. & Tech. 65, 77–82 (2014).

13) S. Shabahang, G. Tao, M. P. Marquez, H. Hu, T. R. Ensley, P. J. Delfyett, and A. F. Abouraddy, “Nonlinear characterization of robust multimaterial chalcogenide nanotapers for infrared supercontinuum generation,” J. Opt. Soc. Am. B 31, 450-457 (2014).

[Highlight: B. Eggleton, Spotlight on Optics, March 2014; Selected for Virtual Journal for Biomedical Optics (VJBO), 9 (5), page 450, Apr. 29, 2014]

12) J. J. Kaufman, R. Ottman, G. Tao, S. Shabahang, X. Liang, S. G. Johnson, Y. Fink, R. Chakrabarti, and A. F. Abouraddy, “In-fiber production of polymeric particles for biosensing and encapsulation,” Proc. Natl. Acad. Sci. USA 110, 15549-15554 (2013).

[Highlight: “Discovery opens doors for advances in biomedical research,” UCF Today, Sept. 23, 2013.]

11) S. Shabahang, G. Tao, J. J Kaufman, and A. F. Abouraddy, “Dispersion characterization of chalcogenide bulk glass, composite fibers, and robust nano-tapers,” J. Opt. Soc. Am. B 30, 2498-2506 (2013).

10) G. Tao, A. M. Stolyarov, and A. F. Abouraddy, “Multimaterial fibers,” I. J. Appl. Glass Science 3, 349-368 (2012). Invited Review paper in the special issue, “Glass and Photonics”.

[Valuable Highlight: Ceramic Tech Today: P. Wray, “Fiber optics of the future: Multifunctionality through multimaterials,” Nov. 27, 2012;  One of the 10 most-accessed articles in I. J. of Appl. Glass Science for 20+ months in a row (Nov. 2012 – June 2014) according to the Wiley Online Library, and was the top-downloaded paper in Dec. 2012, Jan. and May 2013; most accessed paper in 2013; One of the 10 most-cited articles published since 2011 in June 2014.]

09) G. Tao, S. Shabahang, J. J. Kaufman, and A. F. Abouraddy, “Multimaterial preform coextrusion for robust chalcogenide optical fibers and tapers”, Opt. Lett. 37, 2751-2753 (2012).

08) J. J. Kaufman, G. Tao, S. Shabahang, D. S. Deng, X. Liang, S. G. Johnson, Y. Fink, and A. F. Abouraddy, “Structured spheres generated by an in-fibre fluid instability,” Nature 487, 463-467 (2012).

[Valuable Highlight: News & Views: A. Passian and T. Thundat, “Materials science: The abilities of instabilities,” Nature 487, 440-441 (2012);  D. L. Chandler, “Dripping faucets inspire new way of creating structured particles (MIT Homepage Picture),” MIT News Office, 18 July, 2012; featured at Phys.org, nanowerk.com, nanotech-now.com, myscience.cc, rdmag.com (editor’s pick), bioopticsworld.com, nsti.org;  M. Pollmann, “Materialwissenschaft: Wasserhahneffekt produziert vielseitige Nanopartikel,” Spektrum.de (German edition of Scientific American), 18 July, 2012;  B. Abney, “UCF Nanoparticle Discovery Opens Door for Pharmaceuticals,” UCF Today, 7 Aug., 2012: featured at featured at LaserFocusWorld, sciencenewsline.com, bio-medicine.org, nanowerk.com, eurekalert.org, laboratorytalk.com, humanhealthandscience.com, hematologytimes.com, sciencefreaks.co.uk, scicasts.com, www.fisher.co.uk].

07) S. Shabahang, M. P. Marquez, G. Tao, M. U. Piracha, D. Nguyen, P. J. Delfyett, and A. F. Abouraddy, “Octave-spanning infrared supercontinuum generation in robust chalcogenide nano-tapers using picosecond pulses,” Opt. Lett. 37, 4639-4641 (2012).  

06) X. Yu, Y. Zhou, Y. Xu, X. Wang, P. Zhang, G. Tao, and X. Dai, “Studies on mid-IR gain characteristics of Er³⁺-doped chalcogenide glass photonic crystal fibers,” J. Optoelectronics ● Laser in Chinese, 23, 915-921 (2012)

05) S. Dai, L. Lu, G. Tao, Y. Xu, D. Yin, W. Zhang, “Research progress of glass microspheres for optical micro-cavity,” Laser & Optoelectronics Progress in Chinese, 49, 080001 (2012).

04) J. J. Kaufman, G. Tao, S. Shabahang, D. S. Deng, Y. Fink, and A. F. Abouraddy, “Thermal drawing of high-density macroscopic arrays of well-ordered sub-5-nm-diameter nanowires”, Nano Lett. 11, 4768-4773 (2011).

03) G. Tao, H. Guo, L. Feng, M. Lu, W. Wei, and B. Peng, “Formation and properties of a novel heavy-metal chalcogenide glass doped with a high dysprosium concentration,” J. Am. Ceram. Soc. 92, 2226-2229 (2009).

02) L. Feng, H. Guo, G. Tao, M. Lu, W. Wei, B. Peng, “Dy³⁺-doped Ge-In-S-CsI chalcohalide glasses for 1.3 μm optical fiber amplifier,” J. Optoelectron. Adv. Mater. 11, 924-928 (2009).

01) H. Guo, M. Lu, G. Tao, L. Feng, B. Peng, “Research progress of rare earth ions doped chalcogenide glasses for mid-infrared luminescence,” J. Chin. Ceram. Soc. in Chinese, 37, 2150-2156 (2009).

Magazines and Books (Chapters)

02) G. Tao and A. F. Abouraddy, “Robust fibers for delivering infrared light,” SPIE Newsrooms, Dec. 12 2014.  DOI: 10.1117/2.1201411.005660

01) G. Tao, A. F. Abouraddy, A. M. Stolyarov, and Y. Fink, “Multimaterial Fibers,” Chapter 1 of Lab-on-Fiber Technology, A. Cusano, M. Consales, A. Crescitelli, and A. Ricciardi, Eds., (Springer, 2015).

Conference Proceedings

27) J. Kaufman, G. Tao, S. Shabahang, and A. Abouraddy, “Thermal drawing of high-density in-fiber arrays of well-ordered 5-nm-diameter nanowires,” in Photonics and Fiber Technology 2016 (ACOFT, BGPP, NP), OSA Technical Digest (online) (Optical Society of America, 2016), paper ATh2C.2.

26) S. Shabahang, A. Sims, G. Tao, L. Shah, M. Richardson, and A. Abouraddy, “Multi-octave mid-infrared supercontinuum generation in robust chalcogenide nanowires using a thulium fiber laser,” in Photonics and Fiber Technology 2016 (ACOFT, BGPP, NP), OSA Technical Digest (online) (Optical Society of America, 2016), paper AT2C.2.

25) S. Shabahang, F. Tan, J. Perlstein, G. Tao, O. Alvarez, F. Chenard, K. Schepler, and A. Abouraddy, “Robust low-loss multimaterial chalcogenide fiber for infrared applications fabricated by a hybridized approach,” in Photonics and Fiber Technology 2016 (ACOFT, BGPP, NP), OSA Technical Digest (online) (Optical Society of America, 2016), paper ATh4C.5.

24) R. Rezvani Naraghi, G. Tao, J. J. Kaufmann, S. Shabahang, S. Sukhov, A. F. Abouraddy, and A. Dogariu, “Tuning light with photonic particles,” The Conference on Lasers and Electro-Optics (CLEO), San Jose, CA, June 5-10, 2016.

23) S. Shabahang, F. Tan, J. Perlstein, G. Tao, M. Algarni, Y. Bai. O. Alvarez, Y. Bai, O. Alvarez, G. Tsvid, K. Patel, F. Chenard, K. L. Schepler, and A. F. Abouraddy, “Hybridized fabrication of robust low-loss multimaterial chalcogenide fiber for infrared applications,” The Conference on Lasers and Electro-Optics (CLEO), San Jose, CA, June 5-10, 2016.

22) G. Tao and A. F. Abouraddy, “Optical fibers in mid-infrared,” Fiber Society’s Fall Meeting and Technical Conference, Raleigh, NC, 28 – 30 Oct., 2015.

21) G. Tao and A. F. Abouraddy, “Advances in infrared fibers,” 14^th International Conference on the Physics of Non-Crystalline Solids (PNCS-XIV), Niagara Falls, NY USA Sept. 20 - 25, 2015.

20) Y. Sun, S. Dai, P. Zhang, X. Wang, Y. Xu, Z. Liu, F. Chen, C. Wang, Y. Wu, B. Luo. G. Tao, “Fabrication and characterization of multimaterial chalcogenide glass fiber tapers with high numerical apertures,” 14^th International Conference on the Physics of Non-Crystalline Solids (PNCS-XIV), Niagara Falls, NY USA Sept. 20 - 25, 2015.

19) G. Tao, and A. F. Abouraddy, “Advances in infrared fibers,” SPIE DSS 2015, Baltimore, MD, April 20-24, 2015.

18) B. Zhang, H. Ren, M. Zhang, W. Guo, C. Zhai, S. Qi, Y. Yu, B. Luther-Davies, G. Tao, D. Tang, and Z. Yang, “Chalcogenide fibers and image bundles for mid-infrared applications,” the International Commission on Glass (ICG) Annual Meeting 2015, Bangkok, Thailand, Sept. 20-23 2015.

17) X. Wang, C. Cheng, M. Zhu, C. Jiang, F. Liao, Q. Nie, S. Dai, P. Zhang,G. Tao, and X. Zhang, “Far-IR fiber preparation with 'High T’ tellurium chalcohalide glass,” the International Symposium on Non-Oxide and New Optical Glasses (ISNOG) 2014, Jeju, Republic of Korea, Aug. 24-28, 2014.

16) G. Tao and A. F. Abouraddy, “Multimaterial fibers: a new concept in infrared fiber optics,” SPIE DSS 2014, Baltimore, MD, May 5-9 2014.

15) S. Shabahang, G. Tao, K. F. Lee, V. Smolski, K. L. Vodopyanov, M. Fermann, and A. F. Abouraddy, “Mid-infrared supercontinuum generation in robust step-index chalcogenide nanotapers pumped with a thulium fiber laser,” the Conference on Lasers and Electro-Optics (CLEO), San Jose, CA, June 8-13, 2014.

14) G. Tao, H. Ren, S. Shabahang, X. Wang, Z. Yang, and A. F. Abouraddy, “Multimaterial rod-in-tube coextrusion for robust mid-infrared chalcogenide fibers,” OPTO SPIE Photonics West, San Francisco, CA, Feb. 1 – 6 2014.

13) G. Tao and A. F. Abouraddy, “Drawing robust infrared optical fibers from preforms produced by efficient multimaterial stacked coextrusion,” OPTO SPIE Photonics West, San Francisco, CA, Feb. 1 – 6 2014.

12) J. J. Kaufman, G. Tao, S. Shabahang, D. S. Deng, Y. Fink, and A. F. Abouraddy, “What is the smallest-diameter nanowire that may be thermally drawn?” Fiber Society Fall Symposium, Clemson, SC, 23 – 25 Oct., 2013.

11) G. Tao, S. Shabahang, X. Wang, and A. F. Abouraddy, “Efficient disc-to-fiber multimaterial stacked coextrusion for robust infrared optical fibers,” OSA’s 97^th Annual Meeting, Frontiers in Optics 2013/Laser Science XXIX (FiO 2013/LS-XXIX), Orlando, FL, October 6-10 2013. (Finalist in the 2013 Emil Wolf Outstanding Student Paper Competition).

10) S. Shabahang, G. Tao, M. P. Marquez, P. J. Delfyett, and A. F. Abouraddy, “Low threshold supercontinuum generation in highly nonlinear robust step-index chalcogenide nanotapers,” Frontiers in Optics 2013/Laser Science XXIX (FiO 2013/LS-XXIX), Orlando, FL, October 6-10 2013.

09) S. Shabahang, G. Tao, and A. F. Abouraddy, “Highly nonlinear robust step-index chalcogenide nanotapers for octave-spanning supercontinuum generation,” The Conference on Lasers and Electro-Optics (CLEO), San Jose, CA, June 9-14, 2013.

08) G. Tao, S. Shabahang, and A. F. Abouraddy, “One-step multi-material preform extrusion for robust chalcogenide glass optical fibers,” OSA Advanced Photonics Congress, Specialty Optical Fibers & Applications (SOF) Topical Meeting, Colorado Springs, June 17 – 21, 2012.

07) S. Shabahang, G. Tao, M. Piracha, D. Nguyen, P. Delfyett, and A. F. Abouraddy, “Octave-spanning infrared supercontinuum generation in robust chalcogenide nano-tapers,” OSA Advanced Photonics Congress, Nonlinear Photonics (NP), Colorado Springs, June 17 – 21, 2012.

06) S. Shabahang, G. Tao, and A. F. Abouraddy, “Optical dispersion measurements in chalcogenide glass fibers and tapers,” OSA Advanced Photonics Congress, Specialty Optical Fibers & Applications (SOF) Topical Meeting, Colorado Springs, June 17 – 21, 2012.

05) J. Kaufman, G. Tao, S. Shabahang, and A. F. Abouraddy, “Multimaterial fibers for generating structured nanoparticles,” OSA Advanced Photonics Congress, Specialty Optical Fibers & Applications (SOF) Topical Meeting, Colorado Springs, June 17 – 21, 2012.

04) G. Tao, S. Shabahang, J. J. Kaufman, and A. F. Abouraddy, “One-step multi-material preform extrusion for robust chalcogenide glass optical fibers and tapers,”  the Conference on Lasers and Electro-Optics (CLEO), May 6-11, 2012, San Jose Convention Center, San Jose, CA, USA.

03) S. Shabahang, G. Tao, and A. F. Abouraddy, “Over an octave of infrared supercontinuum generation in robust multi-material chalcogenide nano-tapers,” the Conference on Lasers and Electro-Optics (CLEO), May 6-11, 2012, San Jose Convention Center, San Jose, CA, USA.

02) J. Kaufman, G. Tao, S. Shabahang, D. S. Deng, X. Liang, S. Johnson, Y. Fink, and A. F. Abouraddy, “In-fiber fabrication of size-controllable structured particles,” the Conference on Lasers and Electro-Optics (CLEO), May 6-11, 2012, San Jose Convention Center, San Jose, CA, USA.

01) J. J. Kaufman, G. Tao, and A. F. Abouraddy, “Lithographic inscription of micro-optical devices on a multi-material optical fiber tip,” SPIE DSS, Orlando, FL, April 25-29 2011.