Applications of Thin-film Topological Insulators in Ultrafast Optical Devices （Invited）

Kun LIAO; Chentong LI; Xiaoyong HU; Qihuang GONG

doi:10.3788/gzxb20215008.0850210

[1] Qihuang GONG, Wei ZHAO. Ultrafast science to capture ultrafast motions. Ultrafast Science, 2021, 9765859(2021).

[2] X L QI, S C ZHANG. Topological insulators and superconductors. Reviews of Modern Physics, 83, 1057-1110(2011).

[3] S LI, C WANG, Y YIN et al. Novel layered 2D materials for ultrafast photonics. Nanophotonics, 9, 1743-1786(2020).

[4] G ABAJO, F JAVIER. Special issue “2D materials for nanophotonics. ACS Photonics, 4, 2959-2961(2017).

[5] B XU, Y WANG, J PENG et al. Topological insulator Bi₂Se₃ based Q-switched Nd：LiYF₄ nanosecond laser at 1313 nm. Optics Express, 23, 7674-7680(2015).

[6] M HAJLAOUI, E PAPALAZAROU, J MAUCHAIN et al. Ultrafast surface carrier dynamics in the topological insulator Bi₂Te₃. Nano Letters, 12, 3532-3536(2012).

[7] M LANG, L HE, F XIU et al. Revelation of topological surface states in Bi₂Se₃ thin films by in situ al passivation. ACS Nano, 6, 295-302(2012).

[8] G WANG, X G ZHU, Y Y SUN et al. Topological insulator thin films of Bi₂Te₃ with controlled electronic structure. Advanced Materials, 23, 2929-2932(2011).

[9] F XIU, L HE, Y WANG et al. Manipulating surface states in topological insulator nanoribbons. Nature Nanotechnology, 6, 216-221(2011).

[10] H ZHANG, C X LIU, X L QI et al. Topological insulators in Bi₂Se₃， Bi₂Te₃ and Sb₂Te₃ with a single dirac cone on the surface. Nature Physics, 5, 438-442(2009).

[11] L DAI, Z HUANG, Q HUANG et al. Carbon nanotube mode-locked fiber lasers： Recent progress and perspectives. Nanophotonics, 10, 749-775(2021).

[12] J WANG, X WANG, J LEI et al. Recent advances in mode-locked fiber lasers based on two-dimensional materials. Nanophotonics, 9, 2315-2340(2020).

[13] W LIU, M LIU, X LIU et al. Recent advances of 2D materials in nonlinear photonics and fiber lasers. Advanced Optical Materials, 8, 1901631(2020).

[14] B FU, J SUN, G WANG et al. Solution-processed two-dimensional materials for ultrafast fiber lasers. Nanophotonics, 9, 2169-2189(2020).

[15] J CHRISTOPHER, M TALEB, A MAITY et al. Electron-driven photon sources for correlative electron-photon spectroscopy with electron microscopes. Nanophotonics, 9, 4381-4406(2020).

[16] Z FANG, H WANG, X WU et al. Nonlinear terahertz emission in the three-dimensional topological insulator Bi₂Te₃ by terahertz emission spectroscopy. Applied Physics Letters, 115, 191102(2019).

[17] Z LI, Y ZHANG, C CHENG et al. 6.5 GHz Q-switched mode-locked waveguide lasers based on two-dimensional materials as saturable absorbers. Optics Express, 26, 11321-11330(2018).

[18] Y I JHON, J LEE, Y M JHON et al. Topological insulators for mode-locking of 2-mu m fiber lasers. IEEE Journal of Selected Topics in Quantum Electronics, 24, 1102208(2018).

[19] Z YOU, Y SUN, D SUN et al. High performance of a passively Q-switched mid-infrared laser with Bi₂Te₃/graphene composite SA. Optics Letters, 42, 871-874(2017).

[20] U SALEEM, F A PERMATASARI, F ISKANDAR et al. Surface plasmon enhanced nitrogen-doped graphene quantum dot emission by single bismuth telluride nanoplates. Advanced Optical Materials, 5, 1700176(2017).

[21] J LEE, J H LEE. Integrated fiber-optic device based on a combination of a piezoelectric transducer and a bulk-structured Bi₂Te₃ topological insulator for Q-switched mode-locking of a fiber laser. Journal of Lightwave Technology, 35, 2175-2182(2017).

[22] D WU, Z CAI, Y ZHONG et al. 635-nm visible Pr³⁺-doped ZBLAN fiber lasers Q-switched by topological insulators SAs. IEEE Photonics Technology Letters, 27, 2379-2382(2015).

[23] Y H LIN, S F LIN, Y C CHI et al. Using n- and p-type Bi₂Te₃ topological insulator nanoparticles to enable controlled femtosecond mode-locking of fiber lasers. ACS Photonics, 2, 481-490(2015).

[24] J LEE, M JUNG et al. Passively Q-switched 1.89-μm fiber laser using a bulk-structured Bi₂Te₃ topological insulator. IEEE Journal of Selected Topics in Quantum Electronics, 21, 31-36(2015).

[25] Z YU, Y SONG, J TIAN et al. High-repetition-rate Q-switched fiber laser with high quality topological insulator Bi₂Se₃ film. Optics Express, 22, 11508-11515(2014).

[26] J LEE, Y M JHON et al. A femtosecond pulse erbium fiber laser incorporating a saturable absorber based on bulk-structured Bi₂Te₃ topological insulator. Optics Express, 22, 6165-6173(2014).

[27] M JUNG, J LEE et al. A femtosecond pulse fiber laser at 1935 nm using a bulk-structured Bi₂Te₃ topological insulator. Optics Express, 22, 7865-7874(2014).

[28] S CHEN, Y CHEN, M WU et al. Stable Q-switched erbium-doped fiber laser based on topological insulator covered microfiber. IEEE Photonics Technology Letters, 26, 987-990(2014).

[29] Z C LUO, M LIU, H LIU et al. 2 GHz passively harmonic mode-locked fiber laser by a microfiber-based topological insulator saturable absorber. Optics Letters, 38, 5212-5215(2013).

[30] Z LUO, Y HUANG, J WENG et al. 1.06 μm Q-switched ytterbium-doped fiber laser using few-layer topological insulator Bi₂Se₃ as a saturable absorber. Optics Express, 21, 29516-29522(2013).

[31] C ZHAO, H ZHANG, X QI et al. Ultra-short pulse generation by a topological insulator based saturable absorber. Applied Physics Letters, 101, 211106(2012).

[32] B LORENZI, Y TSURIMAKI, A KOBAYASHI et al. Self-powered broadband photo-detection and persistent energy generation with junction-free strained Bi₂Te₃ thin films. Optics Express, 28, 27644-27656(2020).

[33] M YANG, J WANG, Y ZHAO et al. Polarimetric three-dimensional topological insulators/organics thin film heterojunction photodetectors. ACS Nano, 13, 10810-10817(2019).

[34] Y WANG, Y NIU, M CHEN et al. Ultrabroadband， sensitive， and fast photodetection with needle-like EuBiSe₃ single crystal. ACS Photonics, 6, 895-903(2019).

[35] H LIU, X ZHU, X SUN et al. Self-powered broad-band photodetectors based on vertically stacked WSe2/ Bi₂Te₃ p-n heterojunctions. ACS Nano, 13, 13573-13580(2019).

[36] J YAO, G YANG. Flexible and high-performance all-2D photodetector for wearable devices. Small, 14, 1704524(2018).

[37] W TIAN, D LIU, F CAO et al. Hybrid nanostructures for photodetectors. Advanced Optical Materials, 5, 1600468(2017).

[38] J KIM, S PARK, H JANG et al. Highly sensitive， gate-tunable， room-temperature mid-infrared photodetection based on graphene–Bi₂Se₃ heterostructure. ACS Photonics, 4, 482-488(2017).

[39] H QIAO, J YUAN, Z XU et al. Broadband photodetectors based on graphene–Bi₂Te₃ heterostructure. ACS Nano, 9, 1886-1894(2015).

[40] Z CHEN, Z CHENG, J WANG et al. High responsivity， broadband， and fast graphene/silicon photodetector in photoconductor mode. Advanced Optical Materials, 3, 1207-1214(2015).

[41] CW LUO, H J CHEN, C M TU et al. THz generation and detection on dirac fermions in topological insulators. Advanced Optical Materials, 1, 804-808(2013).

[42] F WANG, X NIU, X HU et al. All-optical mode-selective router based on broken anti-pt symmetry. Physical Review Applied, 14(2020).

[43] Z CHAI, X HU, F WANG et al. Ultrafast all-optical switching. Advanced Optical Materials, 5, 1600665(2017).

[44] P YAN, R LIN, S RUAN et al. A practical topological insulator saturable absorber for mode-locked fiber laser. Scientific Reports, 5, 8690(2015).

[45] H CHEN, C WANG, H OUYANG et al. All-optical modulation with 2D layered materials： status and prospects. Nanophotonics, 9, 2107-2124(2020).

[46] H AHMAD, N YUSOFF et al. Temporal and amplitude modulation at c-band region using Bi₂Te₃-based optical modulator. Journal of Modern Optics, 67, 638-646(2020).

[47] S CHEN, L MIAO, X CHEN et al. Few-layer topological insulator for all-optical signal processing using the nonlinear kerr effect. Advanced Optical Materials, 3, 1769-1778(2015).

[48] M JURCZYSZYN, M SIKORA, M CHROBAK et al. Studies of surface states in Bi₂Se₃ induced by the BiSe substitution in the crystal subsurface structure. Applied Surface Science, 528, 146978(2020).

[49] B L HUANG, M KAVIANY. Ab initio and molecular dynamics predictions for electron and phonon transport in bismuth telluride. Physical Review B, 77, 125209(2008).

[50] A LAWAL, A SHAARI, R AHMED et al. First-principles investigations of electron-hole inclusion effects on optoelectronic properties of Bi₂Te₃， a topological insulator for broadband photodetector. Physica B： Condensed Matter, 520, 69-75(2017).

[51] Y CHENG, O COJOCARU-MIRÉDIN, J KEUTGEN et al. Understanding the structure and properties of sesqui-chalcogenides （i.E.， V₂VI₃ or Pn₂Ch₃ （Pn=Pnictogen， Ch=Chalcogen） compounds） from a bonding perspective. Advanced Materials, 31, 1904316(2019).

[52] M ZHAO, J ZHANG, N GAO et al. Actively tunable visible surface plasmons in Bi₂Te₃ and their energy‐harvesting applications. Advanced Materials, 28, 3138-3144(2016).

[53] Q WANG, M SAFDAR, Z WANG et al. Low-dimensional Te-based nanostructures. Advanced Materials, 25, 3915-3921(2013).

[54] N HAN, S I KIM, J D YANG et al. Phase‐change memory in Bi₂Te₃ nanowires. Advanced Materials, 23, 1871-1875(2011).

[55] T FANG, X LI, C HU et al. Complex band structures and lattice dynamics of Bi₂Te₃-based compounds and solid solutions. Advanced Functional Materials, 29, 1900677(2019).

[56] H SHI, D PARKER, M H DU et al. Connecting thermoelectric performance and topological-insulator behavior： Bi₂Te₃ and Bi₂Te₂Se from first principles. Physical Review Applied, 3(2015).

[57] Y GUO, Z LIU, H PENG. A roadmap for controlled production of topological insulator nanostructures and thin films. Small, 11, 3290-3305(2015).

[58] H ZHANG, D T YIMAM, S DE GRAAF et al. Strain relaxation in “2D/2D and 2D/3D systems”： Highly textured mica/Bi₂Te₃， Sb₂Te₃/Bi₂Te₃， and Bi₂Te₃/gete heterostructures. ACS Nano, 15, 2869-2879(2021).

[59] A AHMED, S HAN. Fabrication， micro-structure characteristics and transport properties of co-evaporated thin films of Bi₂Te₃ on aln coated stainless steel foils. Scientific Reports, 11, 4041(2021).

[60] CA HEWITT, Q LI et al. Self-assembled heterostructures： selective growth of metallic nanoparticles on V2-VI3 nanoplates. Advanced Materials, 29, 1702968(2017).

[61] N PERANIO, M WINKLER, M DÜRRSCHNABEL et al. Assessing antisite defect and impurity concentrations in Bi₂Te₃ based thin films by high-accuracy chemical analysis. Advanced functional materials, 23, 4969-4976(2013).

[62] J L MI, N LOCK, T SUN et al. Biomolecule-assisted hydrothermal synthesis and self-assembly of Bi₂Te₃ nanostring-cluster hierarchical structure. ACS Nano, 4, 2523-2530(2010).

[63] Y MA, A JOHANSSON, E AHLBERG et al. A mechanistic study of electrodeposition of bismuth telluride on stainless steel substrates. Electrochimica Acta, 55, 4610-4617(2010).

[64] M SCHEELE, N OESCHLER, K MEIER et al. Synthesis and thermoelectric characterization of Bi₂Te₃ nanoparticles. Advanced Functional Materials, 19, 3476-3483(2009).

[65] Y L CHEN, J G ANALYTIS, J H CHU et al. Experimental realization of a three-dimensional topological insulator， Bi₂Te₃. Science, 325, 178-181(2009).

[66] V GOYAL, D TEWELDEBRHAN, AA BALANDIN. Mechanically-exfoliated stacks of thin films of Bi₂Te₃ topological insulators with enhanced thermoelectric performance. Applied Physics Letters, 97, 133117(2010).

[67] Z DING, D J KING et al. Lithium intercalation and exfoliation of layered bismuth selenide and bismuth telluride. Journal of Materials Chemistry, 19, 2588-2592(2009).

[68] L SUN, Z LIN, J PENG et al. Preparation of few-layer bismuth selenide by liquid-phase-exfoliation and its optical absorption properties. Scientific Reports, 4, 4794(2014).

[69] J L LIU, H WANG, X LI et al. High performance visible photodetectors based on thin two-dimensional Bi₂Te₃ nanoplates. Journal of Alloys and Compounds, 798, 656-664(2019).

[70] G BENDT, S ZASTROW, K NIELSCH et al. Deposition of topological insulator Sb₂Te₃ films by an MOCVD process. Journal of Materials Chemistry A, 2, 8215-8222(2014).

[71] T JIANG, Y ZANG, H SUN et al. Broadband high-responsivity photodetectors based on large-scale topological crystalline insulator snte ultrathin film grown by molecular beam epitaxy. Advanced Optical Materials, 5, 1600727(2017).

[72] R S MAKALA, K JAGANNADHAM, B C SALES. Pulsed laser deposition of Bi₂Te₃-based thermoelectric thin films. Journal of Applied Physics, 94, 3907-3918(2003).

[73] D KONG, W DANG et al. Few-layer nanoplates of Bi₂Se₃ and Bi₂Te₃ with highly tunable chemical potential. Nano Letters, 10, 2245-2250(2010).

[74] H LI, J CAO, W ZHENG et al. Controlled synthesis of topological insulator nanoplate arrays on mica. Journal of the American Chemical Society, 134, 6132-6135(2012).

[75] W WANG, W WANG, B POUDEL et al. High-yield synthesis of single-crystalline antimony telluride hexagonal nanoplates using a solvothermal approach. Journal of the American Chemical Society, 127, 13792-13793(2005).

[76] A ZHUANG, J J LI, Y C WANG et al. Screw‐dislocation‐driven bidirectional spiral growth of Bi₂Se₃ nanoplates. Angewandte Chemie International Edition, 53, 6425-6429(2014).

[77] X CHEN, X C MA, K HE et al. Molecular beam epitaxial growth of topological insulators. Advanced Materials, 23, 1162-1165(2011).

[78] G JIANG, J YI, L MIAO et al. Bismuth telluride nanocrystal： Broadband nonlinear response and its application in ultrafast photonics. Scientific Reports, 8, 2355(2018).

[79] L MIAO, J YI, Q WANG et al. Broadband third order nonlinear optical responses of bismuth telluride nanosheets. Optical Materials Express, 6, 2244-2251(2016).

[80] S CHEN, C ZHAO, Y LI et al. Broadband optical and microwave nonlinear response in topological insulator. Optical Materials Express, 4, 587-596(2014).

[81] D HSIEH, F MAHMOOD, JW MCIVER et al. Selective probing of photoinduced charge and spin dynamics in the bulk and surface of a topological insulator. Physical Review Letters, 107(2011).

[82] S LU, C ZHAO, Y ZOU et al. Third order nonlinear optical property of Bi₂Se₃. Optics Express, 21, 2072-2082(2013).

[83] B SHI, L MIAO, Q WANG et al. Broadband ultrafast spatial self-phase modulation for topological insulator Bi₂Te₃ dispersions. Applied Physics Letters, 107, 151101(2015).

[84] L LU, X TANG, R CAO et al. Broadband nonlinear optical response in few-layer antimonene and antimonene quantum dots： A promising optical kerr media with enhanced stability. Advanced Optical Materials, 5, 1700301(2017).

[85] N HORIUCHI. Nonlinear opportunities. Nature Photonics, 9, 784-784(2015).

[86] M YIN, H P LI, S H TANG et al. Determination of nonlinear absorption and refraction by single z-scan method. Applied Physics B, 70, 587-591(2000).

[87] C P SCHMID, L WEIGL, P GRÖSSING et al. Tunable non-integer high-harmonic generation in a topological insulator. Nature, 593, 385-390(2021).

[88] D PARK, K JEONG, I MAENG et al. Ultrafast photo-response by surface state-mediated optical transitions in topological insulator Bi₂Te₃ nanowire. Advanced Optical Materials, 7, 1900621(2019).

[89] K ZHENG, L B LUO, T F ZHANG et al. Optoelectronic characteristics of a near infrared light photodetector based on a topological insulator Sb₂Te₃ film. Journal of Materials Chemistry C, 3, 9154-9160(2015).

[90] K W MAUSER, S KIM, S MITROVIC et al. Resonant thermoelectric nanophotonics. Nature Nanotechnology, 12, 770-775(2017).

[91] J BESBAS, K BANERJEE et al. Helicity-dependent photovoltaic effect in Bi₂Se₃ under normal incident light. Advanced Optical Materials, 4, 1642-1650(2016).

[92] P OLBRICH, L E GOLUB, T HERRMANN et al. Room-temperature high-frequency transport of dirac fermions in epitaxially grown Sb₂Te₃- and Bi₂Te₃-based topological insulators. Physical Review Letters, 113(2014).

[93] E E NARIMANOV, A V KILDISHEV. Naturally hyperbolic. Nature Photonics, 9, 214-216(2015).

[94] M ESSLINGER, R VOGELGESANG, N TALEBI et al. Tetradymites as natural hyperbolic materials for the near-infrared to visible. ACS Photonics, 1, 1285-1289(2014).

[95] H PLANK, J PERNUL, S GEBERT et al. Infrared/terahertz spectra of the photogalvanic effect in （Bi，Sb）Te based three-dimensional topological insulators. Physical Review Materials, 2(2018).

[96] P HUO, S ZHANG, Y LIANG et al. Hyperbolic metamaterials and metasurfaces： Fundamentals and applications. Advanced Optical Materials, 7, 1801616(2019).

[97] J YANG, K TIAN, Y LI et al. Few-layer Bi₂Te₃： an effective 2D saturable absorber for passive Q-switching of compact solid-state lasers in the 1-um region. Optics Express, 26, 21379-21389(2018).

[98] J QIAO, S ZHAO, K YANG et al. High-quality 2-μm Q-switched pulsed solid-state lasers using spin-coating-coreduction approach synthesized Bi₂Te₃ topological insulators. Photonics Research, 6, 314-320(2018).

[99] M PAWLISZEWSKA, T MARTYNKIEN, A PRZEWŁOKA et al. Dispersion-managed Ho-doped fiber laser mode-locked with a graphene saturable absorber. Optics Letters, 43, 38-41(2018).

[100] J H LIN, G H HUANG et al. Q-switched pulse and mode-locked pulse generation from a Yb³⁺-doped fiber laser based on Bi₂Se₃. IEEE Photonics Journal, 10, 1-10(2018).

[101] W LI, J ZOU, Y HUANG et al. 212-KHz-linewidth， transform-limited pulses from a single-frequency Q-switched fiber laser based on a few-layer Bi₂Se₃ saturable absorber. Photonics Research, 6, C29-C35(2018).

[102] L JIN, X MA, H ZHANG et al. 3 GHz passively harmonic mode-locked Er-doped fiber laser by evanescent field-based nano-sheets topological insulator. Optics Express, 26, 31244-31252(2018).

[103] X LIU, K YANG, S ZHAO et al. High-power passively Q-switched 2.0 um all-solid-state laser based on a Bi₂Te₃ saturable absorber. Photonics Research, 5, 461-466(2017).

[104] K YAN, J LIN, Y ZHOU et al. Bi₂Te₃based passively Q-switched fiber laser with cylindrical vector beam emission. Applied Optics, 55, 3026-3029(2016).

[105] M KOWALCZYK, J BOGUSŁAWSKI, R ZYBAŁA et al. Sb₂Te₃-deposited d-shaped fiber as a saturable absorber for mode-locked Yb-doped fiber lasers. Optical Materials Express, 6, 2273-2282(2016).

[106] P YAN, R LIN, S RUAN et al. A 2.95 GHz， femtosecond passive harmonic mode-locked fiber laser based on evanescent field interaction with topological insulator film. Optics Express, 23, 154-164(2015).

[107] Q WANG, Y CHEN, L MIAO et al. Wide spectral and wavelength-tunable dissipative soliton fiber laser with topological insulator nano-sheets self-assembly films sandwiched by pmma polymer. Optics Express, 23, 7681-7693(2015).

[108] D MAO, B JIANG, X GAN et al. Soliton fiber laser mode locked with two types of film-based Bi₂Te₃ saturable absorbers. Photonics Research, 3, A43-A46(2015).

[109] F JIA, H CHEN, P LIU et al. Nanosecond-pulsed， dual-wavelength passively Q-switched c-cut Nd：YVO4 laser using a few-layer Bi₂Se₃ saturable absorber. IEEE Journal of Selected Topics in Quantum Electronics, 21, 369-374(2015).

[110] B GUO, Y YAO, Y F YANG et al. Topological insulator： Bi₂Se₃/polyvinyl alcohol film-assisted multi-wavelength ultrafast erbium-doped fiber laser. Journal of Applied Physics, 117(2015).

[111] B GUO, Y YAO, Y F YANG et al. Dual-wavelength rectangular pulse erbium-doped fiber laser based on topological insulator saturable absorber. Photonics Research, 3, 94-99(2015).

[112] J BOGUSLAWSKI, G SOBON, R ZYBALA et al. Dissipative soliton generation in Er-doped fiber laser mode-locked by Sb₂Te₃ topological insulator. Optics Letters, 40, 2786-2789(2015).

[113] J BOGUSŁAWSKI, G SOBOŃ, R ZYBAŁA et al. Investigation on pulse shaping in fiber laser hybrid mode-locked by Sb₂Te₃ saturable absorber. Optics Express, 23, 29014-29023(2015).

[114] P YAN, R LIN, H CHEN et al. Topological insulator solution filled in photonic crystal fiber for passive mode-locked fiber laser. IEEE Photonics Technology Letters, 27, 264-267(2014).

[115] Z DOU, Y SONG, J TIAN et al. Mode-locked ytterbium-doped fiber laser based on topological insulator： Bi₂Se₃. Optics Express, 22, 24055-24061(2014).

[116] H YU, H ZHANG, Y WANG et al. Topological insulator as an optical modulator for pulsed solid-state lasers. Laser & Photonics Reviews, 7, L77-L83(2013).

[117] Y CHEN, C ZHAO, S CHEN et al. Large energy， wavelength widely tunable， topological insulator Q-switched erbium-doped fiber laser. IEEE Journal of Selected Topics in Quantum Electronics, 20, 315-322(2013).

[118] C ZHAO, Y ZOU, Y CHEN et al. Wavelength-tunable picosecond soliton fiber laser with topological insulator： Bi₂Se₃ as a mode locker. Optics Express, 20, 27888-27895(2012).

[119] W T SILFVAST. Laser fundamentals(2004).

[120] Z SUN, T HASAN, F TORRISI et al. Graphene mode-locked ultrafast laser. ACS Nano, 4, 803-810(2010).

[121] H LIU, X W ZHENG, M LIU et al. Femtosecond pulse generation from a topological insulator mode-locked fiber laser. Optics Express, 22, 6868-6873(2014).

[122] J LI, H LUO, L WANG et al. 3-μm mid-infrared pulse generation using topological insulator as the saturable absorber. Optics Letters, 40, 3659-3662(2015).

[123] H ZHANG, X ZHANG, C LIU et al. High-responsivity， high-detectivity， ultrafast topological insulator Bi₂Se₃/silicon heterostructure broadband photodetectors. ACS Nano, 10, 5113-5122(2016).

[124] J YAO, J SHAO, Y WANG et al. Ultra-broadband and high response of the Bi₂Te₃-Si heterojunction and its application as a photodetector at room temperature in harsh working environments. Nanoscale, 7, 12535-12541(2015).

[125] J LIU, Y LI, Y SONG et al. Bi₂Te₃ photoconductive detectors on si. Applied Physics Letters, 110, 141109(2017).

[126] J YAO, Z ZHENG, G YANG. All-layered 2D optoelectronics： a high-performance UV-vis-NIR broadband SnSe photodetector with Bi₂Te₃ topological insulator electrodes. Advanced Functional Materials, 27, 1701823(2017).

[127] M YANG, J WANG, Y ZHAO et al. Three-dimensional topological insulator Bi₂Te₃/organic thin film heterojunction photodetector with fast and wideband response from 450 to 3500 nanometers. ACS Nano, 13, 755-763(2019).

[128] B N SHIVANANJU, X BAO, W YU et al. Graphene heterostructure integrated optical fiber bragg grating for light motion tracking and ultrabroadband photodetection from 400 nm to 10.768 µm. Advanced Functional Materials, 29, 1807274(2019).

[129] Y SHEN, N C HARRIS, S SKIRLO et al. Deep learning with coherent nanophotonic circuits. Nature Photonics, 11, 441-446(2017).