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SCIENTIA SINICA Informationis, Volume 46, Issue 8: 1156-1174(2016) https://doi.org/10.1360/N112016-00059

Optoelectronic devices and integration technologies

More info
  • ReceivedMar 23, 2016
  • AcceptedMay 26, 2016
  • PublishedAug 5, 2016

Abstract

Optoelectronics integration technology has several outstanding advantages, including low power consumption, high speed, high reliability, and small size. It is well known as one of the key technologies to break through the bottlenecks of current information networks, such as bandwidth, power consumption, and intelligence. In this paper, we review recent advances in China on optoelectronic devices and integration technology, and its applications in the fields of optical communication and information processing, ultrahigh resolution imaging and display, and wide-band gap optoelectronic device. In addition to recent progress, the current research situation, experiences, and infrastructure associated with optoelectronics integration technology are also presented. The main research directions and the contents of optoelectronic devices and integration technology are also analyzed in detail with a view towards forward development in the next five years.


Funded by

国家自然科学基金(61321063)

国家自然科学基金(61090390)

国家自然科学基金(61522509)

国家自然科学基金(61535012)

国家高技术研究发展计划(2011AA010303)

国家高技术研究发展计划(2015AA017102)


References

[1] Li M, Chen X, Su Y, et al. Photonic integration circuits in China. IEEE J Quant Electron, 2016, 52: 0601017. Google Scholar

[2] Li M, Zhu N H. Microwave photonics shines in China. IEEE Photo Soci Newsl, 2016, 30: 4-14. Google Scholar

[3] Bougioukos M, Kouloumentas C, Spyropoulou M, et al. Multi-format all-optical processing based on a large-scale, hybridly integrated photonic circuit. Opt Express, 2011, 19: 11479-11489 CrossRef Google Scholar

[4] Bougioukos M, Richter T, Kouloumentas C, et al. Phase-incoherent DQPSK wavelength conversion using a photonic integrated circuit. IEEE Photon Tech Lett, 2011, 23: 1649-1651 CrossRef Google Scholar

[5] Cemlyn B R, Labukhin D, Henning I D, et al. Dynamic transitions in a photonic integrated circuit. IEEE J Quant Electron, 2012, 48: 261-268 CrossRef Google Scholar

[6] Chen L, Sohdi A, Bowers J E, et al. Electronic and photonic integrated circuits for fast data center optical circuit switches. IEEE Commun Mag, 2013, 51: 53-59. Google Scholar

[7] Dal Bosco A K, Kanno K, Uchida A, et al. Cycles of self-pulsations in a photonic integrated circuit. Phys Rev E, 2015, 92: 062905-59 CrossRef Google Scholar

[8] Ding Y H, Ou H Y, Xu J, et al. Silicon photonic integrated circuit mode multiplexer. IEEE Photon Tech Lett, 2013, 25: 648-651 CrossRef Google Scholar

[9] Englund D R. Towards scalable networks of solid-state quantum memories in a photonic integrated circuit (presentation recording). In: Proceedings of SPIE Active Photonic Materials VII, San Diego, 2015. 9546. Google Scholar

[10] Evans P, Fisher M, Malendevich R, et al. 1.12 Tb/s superchannel coherent PM-QPSK InP transmitter photonic integrated circuit (PIC). Opt Express, 2011, 19: 154-158. Google Scholar

[11] Evans P, Fisher M, Malendevich R, et al. Multi-channel coherent PM-QPSK InP transmitter photonic integrated circuit (PIC) operating at 112 Gb/s per wavelength. In: Proceedings of Optical Fiber Communication Conference/National Fiber Optic Engineers Conference, Los Angeles, 2011. 1-3. Google Scholar

[12] Fandino J S, Domenech J D, Munoz P, et al. Design and experimental characterization of an InP photonic integrated circuit working as a receiver for frequency-modulated direct-detection microwave photonic links. In: Proceedings of SPIE Integrated Optics: Devices, Materials, and Technologies XVII, San Francisco, 2013. 8627: 1-8. Google Scholar

[13] Germer S, Cherkouk C, Rebohle L, et al. Si-based light emitter in an integrated photonic circuit for smart biosensor applications. In: Proceedings of SPIE Integrated Photonics: Materials, Devices, and Applications II, Grenoble, 2013. 8767: 1-13. Google Scholar

[14] Guan B B, Scott R P, Qin C, et al. Free-space coherent optical communication with orbital angular, momentum multiplexing/demultiplexing using a hybrid 3D photonic integrated circuit. Opt Express, 2014, 22: 145-156 CrossRef Google Scholar

[15] Guzzon R S, Norberg E J, Coldren L A. Spurious-free dynamic range in photonic integrated circuit filters with semiconductor optical amplifiers. IEEE J Quant Electron, 2012, 48: 269-278 CrossRef Google Scholar

[16] Haney M W. How will photonic integrated circuit technology develop? In: Proceedings of SPIE Silicon Photonics VIII, San Francisco, 2013. 8629: 1-6. Google Scholar

[17] Hasan M, Guemri R, Maldonado-Basilio R, et al. Theoretical analysis and modeling of a photonic integrated circuit for frequency 8-tupled and 24-tupled millimeter wave signal generation. Opt Lett, 2014, 39: 6950-6953 CrossRef Google Scholar

[18] Hasan M, Guemri R, Maldonado-Basilio R, et al. Theoretical analysis and modeling of a photonic integrated circuit for frequency 8-tupled and 24-tupled millimeter wave signal generation. Opt Lett, 2015, 40: 5710-5710 CrossRef Google Scholar

[19] Hasan M, Hall T. Cascade photonic integrated circuit architecture for electro-optic in-phase quadrature/single sideband modulation or frequency conversion. Opt Lett, 2015, 40: 5038-5041 CrossRef Google Scholar

[20] Hasan M, Maldonado-Basilio R, Hall T J. Dual-function photonic integrated circuit for frequency octo-tupling or single-side-band modulation. Opt Lett, 2015, 40: 2501-2504 CrossRef Google Scholar

[21] Heck M J R, Bauters J F, Davenport M L, et al. Hybrid silicon photonic integrated circuit technology. IEEE J Sel Top Quant, 2013, 19: 6100117-2504 CrossRef Google Scholar

[22] Heck M J R, Davenport M L, Srinivasan S, et al. Optimization of the hybrid silicon photonic integrated circuit platform. In: Proceedings of SPIE Novel In-Plane Semiconductor Lasers XII, San Francisco, 2013. 8640: 1-10. Google Scholar

[23] Huang W P, Han L, Mu J W. A rigorous circuit model for simulation of large-scale photonic integrated circuits. IEEE Photon J, 2012, 4: 1622-1638 CrossRef Google Scholar

[24] Kazmierski C. Electro-absorption-based fast photonic integrated circuit sources for next network capacity scaling. J Opt Commun Netw, 2012, 4: 8-16 CrossRef Google Scholar

[25] Kervella G, van Dijk F, Pillet G, et al. Optoelectronic cross-injection locking of a dual-wavelength photonic integrated circuit for low-phase-noise millimeter-wave generation. Opt Lett, 2015, 40: 3655-3658 CrossRef Google Scholar

[26] Liow T Y, Ang K W, Fang Q, et al. Silicon photonics technologies for monolithic electronic-photonic integrated circuit applications. In: Proceedings of the 10th IEEE International Conference on Solid-State and Integrated Circuit Technology, Shannghai, 2010. 29-32. Google Scholar

[27] Mao D P, Qiao X, Dong L. Design of nano-opto-mechanical reconfigurable photonic integrated circuit. J Lightw Tech, 2013, 31: 1660-1669 CrossRef Google Scholar

[28] Nagarajan R, Lambert D, Kato M, et al. Five-channel, 114 Gbit/s per channel, dual carrier, dual polarisation, coherent QPSK, monolithic InP receiver photonic integrated circuit. Electron Lett, 2011, 47: 555-556 CrossRef Google Scholar

[29] Nagarajan R, Rahn J, Kato M, et al. 10 channel, 45.6 Gb/s per channel, polarization-multiplexed DQPSK, InP receiver photonic integrated circuit. J Lightw Tech, 2011, 29: 386-395. Google Scholar

[30] Ruocco A, Fiers M, Vanslembrouck M, et al. Multi-parameter extraction from SOI photonic integrated circuits using circuit simulation and evolutionary algorithms. In: Proceedings of SPIE Smart Photonic and Optoelectronic Integrated Circuits XVII, San Francisco, 2015. 9366: 1-9. Google Scholar

[31] Shiue R J, Gao Y D, Wang Y F, et al. High-responsivity Graphene-Boron nitride photodetector and autocorrelator in a silicon photonic integrated circuit. Nano Lett, 2015, 15: 7288-7293 CrossRef Google Scholar

[32] Snyder B, Corbett B, O'brien P. Hybrid Integration of the wavelength-tunable laser with a silicon photonic integrated circuit. J Lightw Tech, 2013, 31: 3934-3942 CrossRef Google Scholar

[33] Spyropoulou M, Bougioukos M, Giannoulis G, et al. Large-scale photonic integrated circuit for multi-format regeneration and wavelength conversion. In: Proceedings of Optical Fiber Communication Conference/National Fiber Optic Engineers Conference, Los Angeles, 2011. 1-3. Google Scholar

[34] Stanton E J, Heck M J R, Bovington J, et al. Multi-octave spectral beam combiner on ultra-broadband photonic integrated circuit platform. Opt Express, 2015, 23: 11272-11283 CrossRef Google Scholar

[35] Stopinski S, Malinowski M, Piramidowicz R, et al. Data readout system utilizing photonic integrated circuit. Nucl Instrum Meth A, 2013, 725: 183-186 CrossRef Google Scholar

[36] Summers J, Vallaitis T, Evans P, et al. Monolithic InP-based coherent transmitter photonic integrated circuit with 2.25 Tbit/s capacity. Electron Lett, 2014, 50: 1150-1151. Google Scholar

[37] Theurer M, Gobel T, Stanze D, et al. Photonic-integrated circuit for continuous-wave THz generation. Opt Lett, 2013, 38: 3724-3726 CrossRef Google Scholar

[38] van Acoleyen K, Ryckeboer E, Bogaerts W, et al. Efficient light collection and direction-of-arrival estimation using a photonic integrated circuit. IEEE Photon Tech Lett, 2012, 24: 933-935 CrossRef Google Scholar

[39] van Dijk F, Lamponi M, Chtioui M, et al. Photonic integrated circuit on InP for millimeter wave generation. In: Proceedings of SPIE Integrated Optics: Devices, Materials, and Technologies XVIII, San Francisco, 2014. 8988: 1-6. Google Scholar

[40] Wang Z, Lee H C, Vermeulen D, et al. Silicon photonic integrated circuit swept-source optical coherence tomography receiver with dual polarization, dual balanced, in-phase and quadrature detection. Biomed Opt Express, 2015, 6: 2562-2574 CrossRef Google Scholar

[41] Xu K, Cheng Z Z, Wong C Y, et al. UWB monocycle pulse generation based on colourless silicon photonic integrated circuit. Electron Lett, 2013, 49: 1291-1292 CrossRef Google Scholar

[42] Yi Y J, Wang H R, Liu Y, et al. Multilayer hybrid waveguide amplifier for three-dimension photonic integrated circuit. IEEE Photon Tech Lett, 2015, 27: 2411-2413 CrossRef Google Scholar

[43] Zhong Q H, Tian Z B, Veerasubramanian V, et al. Thermally controlled coupling of a rolled-up microtube integrated with a waveguide on a silicon electronic-photonic integrated circuit. Opt Lett, 2014, 39: 2699-2702 CrossRef Google Scholar

[44] Alekseyev L, Narimanov E, Khurgin J. Super-resolution imaging via spatiotemporal frequency shifting and coherent detection. Opt Express, 2011, 19: 22350-22357 CrossRef Google Scholar

[45] Ashida Y, Ueda M. Precise multi-emitter localization method for fast super-resolution imaging. Opt Lett, 2016, 41: 72-75 CrossRef Google Scholar

[46] Babcock H P, Moffitt J R, Cao Y L, et al. Fast compressed sensing analysis for super-resolution imaging using L1-homotopy. Opt Express, 2013, 21: 28583-28596 CrossRef Google Scholar

[47] Beliveau B J, Boettiger A N, Avendano M S, et al. Single-molecule super-resolution imaging of chromosomes and in situ haplotype visualization using Oligopaint FISH probes. Nat Commun, 2015, 6: 7147-28596 CrossRef Google Scholar

[48] Carles G, Downing J, Harvey A R. Super-resolution imaging using a camera array. Opt Lett, 2014, 39: 1889-1892 CrossRef Google Scholar

[49] Conkey D B, Caravaca-Aguirre A M, Dove J D, et al. Super-resolution photoacoustic imaging through a scattering wall. Nat Commun, 2015, 6: 7902-1892 CrossRef Google Scholar

[50] Darafsheh A, Guardiola C, Palovcak A, et al. Optical super-resolution imaging by high-index microspheres embedded in elastomers. Opt Lett, 2015, 40: 5-8 CrossRef Google Scholar

[51] Darafsheh A, Limberopoulos N I, Derov J S, et al. Advantages of microsphere-assisted super-resolution imaging technique over solid immersion lens and confocal microscopies. Appl Phys Lett, 2014, 104: 061117-8 CrossRef Google Scholar

[52] Dempsey G T, Vaughan J C, Chen K H, et al. Evaluation of fluorophores for optimal performance in localization-based super-resolution imaging. Nat Methods, 2011, 8: 1027-1036 CrossRef Google Scholar

[53] Dong S Y, Horstmeyer R, Shiradkar R, et al. Aperture-scanning Fourier ptychography for 3D refocusing and super-resolution macroscopic imaging. Opt Express, 2014, 22: 13586-13599 CrossRef Google Scholar

[54] Du Y J, Zhang H, Zhao M Y, et al. Faster super-resolution imaging of high density molecules via a cascading algorithm based on compressed sensing. Opt Express, 2015, 23: 18563-18576 CrossRef Google Scholar

[55] Duan Y B, Barbastathis G, Zhang B L. Classical imaging theory of a microlens with super-resolution. Opt Lett, 2013, 38: 2988-2990 CrossRef Google Scholar

[56] Geissbuehler S, Sharipov A, Godinat A, et al. Live-cell multiplane three-dimensional super-resolution optical fluctuation imaging. Nat Commun, 2014, 5: 5830-2990 CrossRef Google Scholar

[57] Hao X, Liu X, Kuang C F, et al. Far-field super-resolution imaging using near-field illumination by micro-fiber. Appl Phys Lett, 2013, 102: 013104-2990 CrossRef Google Scholar

[58] Hardie R C, Barnard K J, Ordonez R. Fast super-resolution with affine motion using an adaptive Wiener filter and its application to airborne imaging. Opt Express, 2011, 19: 26208-26231 CrossRef Google Scholar

[59] Izeddin I, El Beheiry M, Andilla J, et al. PSF shaping using adaptive optics for three-dimensional single-molecule super-resolution imaging and tracking. Opt Express, 2012, 20: 4957-4967 CrossRef Google Scholar

[60] Jia S, Vaughan J C, Zhuang X W. Isotropic three-dimensional super-resolution imaging with a self-bending point spread function. Nat Photon, 2014, 8: 302-306 CrossRef Google Scholar

[61] Kozawa Y, Kusama Y, Sato S, et al. Super-resolution imaging of lateral distribution for the blue-light emission of an InGaN single-quantum-well structure utilizing the stimulated emission depletion effect. Opt Express, 2014, 22: 22575-22582 CrossRef Google Scholar

[62] Li L, Guo W, Yan Y Z, et al. Label-free super-resolution imaging of adenoviruses by submerged microsphere optical nanoscopy. Light-Sci Appl, 2013, 2: e104-22582 CrossRef Google Scholar

[63] Lu D L, Liu Z W. Hyperlenses and metalenses for far-field super-resolution imaging. Nat Commun, 2012, 3: 1205. Google Scholar

[64] Pan D, Hu Z, Qiu F W, et al. A general strategy for developing cell-permeable photo-modulatable organic fluorescent probes for live-cell super-resolution imaging. Nat Commun, 2014, 5: 5573-22582 CrossRef Google Scholar

[65] Piliarik M, Sandoghdar V. Direct optical sensing of single unlabelled proteins and super-resolution imaging of their binding sites. Nat Commun, 2014, 5: 4495. Google Scholar

[66] See C W, Hu F, Chuang C J, et al. Super-resolution imaging using proximity projection grating and structured light illumination. Opt Express, 2013, 21: 15155-15167 CrossRef Google Scholar

[67] Sobieranski A C, Inci F, Tekin H C, et al. Portable lensless wide-field microscopy imaging platform based on digital inline holography and multi-frame pixel super-resolution. Light-Sci Appl, 2015, 4: e346-15167 CrossRef Google Scholar

[68] Tang H H, Liu P K. Long-distance super-resolution imaging assisted by enhanced spatial Fourier transform. Opt Express, 2015, 23: 23613-23623 CrossRef Google Scholar

[69] Tang Y, Wang X, Zhang X, et al. Sub-nanometer drift correction for super-resolution imaging. Opt Lett, 2014, 39: 5685-5688 CrossRef Google Scholar

[70] Wang F F, Lai H S S, Liu L Q, et al. Super-resolution endoscopy for real-time wide-field imaging. Opt Express, 2015, 23: 16803-16811 CrossRef Google Scholar

[71] Willets K A, Weber M L. Super-resolution imaging of surface-enhanced Raman scattering hot spots under electrochemical control. In: Proceedings of SPIE Micro- and Nanotechnology Sensors, Systems, and Applications VII, 2015. 9467. Google Scholar

[72] Wu K D, Wang G P. One-dimensional Fibonacci grating for far-field super-resolution imaging. Opt Lett, 2013, 38: 2032-2034 CrossRef Google Scholar

[73] An Q, Jaramillo-Botero A, Liu W G, et al. Reaction Pathways of GaN (0001) Growth from Trimethylgallium and Ammonia versus Triethylgalliunn and Hydrazine Using First Principle Calculations. J Phys Chem C, 2015, 119: 4095-4103 CrossRef Google Scholar

[74] Appavoo K, Liu M Z, Sfeir M Y. Role of size and defects in ultrafast broadband emission dynamics of ZnO nanostructures. Appl Phys Lett, 2014, 104: 133101-4103 CrossRef Google Scholar

[75] Appavoo K, Sfeir M Y. Enhanced broadband ultrafast detection of ultraviolet emission using optical Kerr gating. Rev Sci Instrum, 2014, 85: 055114-4103 CrossRef Google Scholar

[76] Cai Y, Han Z H, Wang X X, et al. Analysis of threshold current behavior for bulk and quantum-well germanium laser structures. IEEE J Sel Top Quant, 2013, 19: 1901009-4103 CrossRef Google Scholar

[77] Cai Z H, Narang P, Atwater H A, et al. Cation-mutation design of quaternary nitride semiconductors lattice-matched to GaN. Chem Mater, 2015, 27: 7757-7764 CrossRef Google Scholar

[78] Chang H X, Cheng J S, Liu X Q, et al. Facile synthesis of wide-bandgap fluorinated graphene semiconductors. Chem-Eur J, 2011, 17: 8896-8903 CrossRef Google Scholar

[79] Chen Q S, Jiang Y N, Yan J Y, et al. Modeling of ammonothermal growth processes of GaN crystal in large-size pressure systems. Res Chem Intermediat, 2011, 37: 467-477 CrossRef Google Scholar

[80] Chu T, Ilatikhameneh H, Klimeck G, et al. Electrically tunable bandgaps in bilayer MoS2. Nano Lett, 2015, 15: 8000-8007 CrossRef Google Scholar

[81] Claudel A, Chowanek Y, Blanquet E, et al. Aluminum nitride homoepitaxial growth on polar and non-polar AlN PVT substrates by high temperature CVD (HTCVD). Phys Status Solid C, 2011, 8: 2019-2021 CrossRef Google Scholar

[82] Gulbahar B, Akan O B. A communication theoretical modeling of single-walled carbon nanotube optical nanoreceivers and broadcast power allocation. IEEE Tran Nanotech, 2012, 11: 395-405 CrossRef Google Scholar

[83] Kang K, Xie S E, Huang L J, et al. High-mobility three-atom-thick semiconducting films with wafer-scale homogeneity. Nature, 2015, 520: 656-660 CrossRef Google Scholar

[84] Ko W, Lee S, Myoung N, et al. Solution processed vertically stacked ZnO sheet-like nanorod p-n homojunctions and their application as UV photodetectors. J Mater Chem C, 2016, 4: 142-149. Google Scholar

[85] Lashkarev G V, Shtepliuk I I, Ievtushenko A I, et al. Properties of solid solutions, doped film, and nanocomposite structures based on zinc oxide. Low Temp Phys, 2015, 41: 129-140 CrossRef Google Scholar

[86] Li Z Y, Yuan X M, Fu L, et al. Room temperature GaAsSb single nanowire infrared photodetectors. Nanotechnology, 2015, 26: 445202-140 CrossRef Google Scholar

[87] Majety S, Cao X K, Dahal R, et al. Semiconducting hexagonal boron nitride for deep ultraviolet photonics. In: Proceedings of SPIE Quantum Sensing and Nanophotonic Devices Ix, San Francisco, 2012. 8268: 1-8. Google Scholar

[88] Naeemullah, Murtaza G, Khenata R, et al. Phase transition, electronic and optical properties of NaCl under pressure. Mod Phys Lett B, 2014, 28: 1450062. Google Scholar

[89] Nagar S, Chakrabarti S. P-type ZnO films by phosphorus doping using plasma immersion ion-implantation technique. In: Proceedings of SPIE Oxide-Based Materials and Devices IV, San Francisco, 2013. 8626: 1-8. Google Scholar

[90] Nagar S, Sinha B, Mandal A, et al. Influence of Li implantation on the optical and electrical properties of ZnO film. In: Proceedings of SPIE Oxide-Based Materials and Devices II, San Francisco, 2011. 7940: 1-7. Google Scholar

[91] Nam S H, Boo J H. Rutile structured SnO2 nanowires synthesized with metal catalyst by thermal evaporation method. J Nanosci Nanotech, 2012, 12: 1559-1562 CrossRef Google Scholar

[92] Nyawo T G, Ndwandwe O M. Reactive DC sputter deposition and charactersation of AlN thin films. In: Proceedings of SAIP2012: the 57th Annual Conference of the South African Institute of Physics, Pretoria, 2012. 180-185. Google Scholar

[93] Okell W A, Witting T, Fabris D, et al. Temporal broadening of attosecond photoelectron wavepackets from solid surfaces. Optica, 2015, 2: 383-387 CrossRef Google Scholar

[94] Ou H Y, Ou Y Y, Argyraki A, et al. Advances in wide bandgap SiC for optoelectronics. Eur Phys J B, 2014, 87: 58-387 CrossRef Google Scholar

[95] Park J S, Lee J M, Hwang S K, et al. A ZnO/N-doped carbon nanotube nanocomposite charge transport layer for high performance optoelectronics. J Mater Chem, 2012, 22: 12695-12700 CrossRef Google Scholar

[96] Park S H, Yuan G, Chen D T, et al. Wide bandgap III-Nitride nanomembranes for optoelectronic applications. Nano Lett, 2014, 14: 4293-4298 CrossRef Google Scholar

[97] Park Y S. Wide bandgap III-Nitride semiconductors: opportunities for future optoelectronics. Opto-Electron Rev, 2001, 9: 117-124. Google Scholar

[98] Sang N X, Beng T C, Jie T, et al. Fabrication of p-type ZnO nanorods/n-GaN film heterojunction ultraviolet light-emitting diodes by aqueous solution method. Phys Status Solid A, 2013, 210: 1618-1623 CrossRef Google Scholar

[99] Tan H, Fan C, Ma L, et al. Single-crystalline InGaAs nanowires for room-temperature high-performance near-infrared photodetectors. Nano-Micro Lett, 2016, 8: 29-35 CrossRef Google Scholar

[100] Tournier D, Brosselard P, Raynaud C, et al. Wide band gap semiconductors benefits for high power, high voltage and high temperature applications. Adv Mater Res-Switz, 2011, 324: 46-51 CrossRef Google Scholar

[101] Ullah N, Ullah H, Murtaza G, et al. Structural phase transition and optoelectronic properties of ZnS under pressure. J Optoelectron Adv M, 2015, 17: 1272-1277. Google Scholar

[102] Weiss N O, Zhou H L, Liao L, et al. Graphene: an emerging electronic material. Adv Mater, 2012, 24: 5782-5825 CrossRef Google Scholar

[103] Wen Z, Luo J S, Zhu Y F, et al. Cohesive-energy-resolved bandgap of nanoscale graphene derivatives. Chemphyschem, 2014, 15: 2563-2568 CrossRef Google Scholar

[104] Zeggai O, Ould-Abbas A, Bouchaour M, et al. Biological detection by high electron mobility transistor (HEMT) based AlGaN/GaN. Phys Status Solid C, 2014, 11: 274-279 CrossRef Google Scholar

[105] Zhou M, Duan W H, Chen Y, et al. Single layer lead iodide: computational exploration of structural, electronic and optical properties, strain induced band modulation and the role of spin-orbital-coupling. Nanoscale, 2015, 7: 15168-15174 CrossRef Google Scholar

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