Faculty

Prof. Jialin Sun

Professor

Room C321, Building of the School of Science

Department of Physics, Tsinghua University,

Beijing 100084, P.R. China

Phone:86(10)-62772687

Fax:86(10)-62781604

jlsun@tsinghua.edu.cn

Bibliography

Education:

· 1985 B.S. Department of Physics, Heilongjiang University

· 1996 Ph.D Department of Physics, Kharkov State University, Ukraine

· 1998 Post Dr. Department of Physics, Tsinghua University

Employment:

· 1985-1996 TA, Lecturer, Department of Physics, Heilongjiang University

· 1996-present Lecturer,Associate Professor,Professor, Department of Physics, Tsinghua University

Teaching

1998- present Undergraduate Course “Advanced Physics Experiment”

“Modern Physics Experiment” “General Physics Experiment”

Research Interests

Member of the State Key Laboratory of Low-Dimensional Quantum Physics and Department of Physics, Tsinghua University. The main research area lies in the nanotechnology and nano-optoelectronics. The current interests relates to the fabrication of low-dimensional nanostructure and corresponding photoelectronic characteristics study.



Selected Publications

Have published about 150 papers and owned 20 national patents.Selected Papers:


        [1] High-Performance     Ultrabroadband Photodetector Based on Photothermoelectric Effect,     ACS Applied Materials & Interfaces, 2022, 14(25), 29077–29086

[2] Local large     temperature difference and ultra-wideband photothermoelectric response of     the silver nanostructure film/carbon nanotube film heterostructure, Nature Communications,     2022, 13(1),1835

[3] Gamma-Ray Radiation Stability of     Mixed-Cation Lead Mixed-Halide Perovskite Single Crystals, Advanced Optical Materials2022,     10(3), 2102069

[4] Measurement of     photothermal conversion efficiency for CNT films utilizing Raman spectrum, Nanomaterials,     2022, 12(7), 1101

[5] γ-Ray Radiation     Hardness of CsPbBr3 Single Crystals and Single-Carrier Devices ACS Applied Materials and Interfaces,2022, 1433),37904-37915

[6] Super-resolved     discrimination of nanoscale defects in low-dimensional materials by     near-field photoluminescence spectral imaging, Optics Letters, 2022,47(16)4227-4230

[7] Transparent     humidity sensor with high sensitivity via a facile and scalable way based     on liquid-phase exfoliated MoO3-x nanosheets, Sensors     and Actuators Reports, 2022, 4,     100092

[8] Unravelling     the Effect of Halogen Ion Substitution on the Noise of Perovskite Single     Crystal Photodetector, The Journal of Physical Chemistry     Letters, 2022, 13, 7831−7837

[9] Stability diagrams     of two optically mutual-injected quantum cascade lasers, AIP Advances, 2021, 11(1), 015320

[10] Oxidized Eutectic     Gallium-Indium (EGaIn) Nanoparticles for Broadband Light Response in     Graphene-Based Photodetector, Materials Advances, 2021, 2,     4414–4422

[11] Ultra-wideband     self-powered photodetector based on suspended reduced graphene oxide with     asymmetric metal contactsRSC Advances, 2021, 11, 19482 – 19491

[12] Electrically     driven transport of photoinduced hot carriers in carbon nanotube fibers, Optics     Letters, 2021, 46(20), 5228-5231

[13] Significantly     enhanced photoresponse of carbon nanotube films modified with cesium     tungsten bronze nanoclusters in the visible to short-wave infrared rangeRSC Advances, 2021, 11,     39646

[14] High responsivity photodetector based on     suspended monolayer graphene/RbAg4I5 composite     nanostructure, ACS Applied Materials & Interfaces, 2020, 12 (45), 50763-50771

[15] Facile fabrication of eutectic gallium-indium alloy nanostructure and     application in photodetection, Nanotechnology, 2020, 31(14), 145703

[16] Strongly enhanced local electromagnetic field in mid-infrared and terahertz     photodetectors employing a hybrid antenna, AIP     Advances, 2020,     10(1), 015048

[17] Thermal Localization Enhanced Fast Photothermoelectric     Response in a Quasi-one-dimensional Flexible NbS3 Photodetector,     ACS     Applied Materials & Interfaces, 2020, 12, 14165−14173

[18] Ultrabroadband,     Fast, and Flexible Photodetector Based on HfTe5     Crystal, Advanced Optical Materials,     2020, 8(20), 2000833

[19] Optically Monitored Electric-Field-Induced Phase     Transition in Vanadium Dioxide Crystal Film, Crystals,     2020, 10(9), 764

[20] Growth mechanism and photoelectric properties of a silver nanowire network     prepared by solid state ionics method, Nanotechnology, 2020, 31(45), 455201

[21] Simple method preparation for ultrathin VO2 thin film and control: nanoparticle morphology and optical transmittance, Japanese Journal of Applied Physics, 2019, 58,

[22] Optical Modulation of     Charge Transport in Layered Graphene System by Superionic Conductor RbAg4I5,     Advanced     Materials Interfaces, 2019,     6, 1900094

[23] Bolometric terahertz detection based on     suspended carbon nanotube fibers Applied Physics Express201912(9)096505

[24] Ultra-broadband     self-powered reduced graphene oxide photodetectors with annealing     temperature-dependent responsivityCarbon, 2019153274-284

[25] Gate-tunable ion-electron hybrid phototransistor based     on a graphene/RbAg4I5 composite, Journal of Materials     Chemistry C, 2019, 7, 13253-13260

[26] Optically mutual-injected terahertz quantum     cascade lasers for self-mixing velocity measurementsOptics Express201927(19)27076-27087

[27] Superionic     Modulation of PMMA-assisted Suspended Few-Layer Graphene Nanocomposite for     High-Performance Broadband Photodetectors, ACS Applied Materials &     Interfaces, 2019, 11, 7, 7600-7606

[28] Tunable positive     and negative photoconductive photodetector based on a gold/graphene/p-type     silicon heterojunction, Journal of Materials     Chemistry C, 2019, 7, 887-896

[29] Self-assembled gold micro/nanostructure     arrays based on superionic conductor RbAg4I5 films, Nanotechnology,     2019, 30(2), 025602

[30] Investigation on crystallization of CH3NH3PbI3     perovskite and its intermediate phase from polar aprotic solvents, Crystal     Growth & Design, 2019, 19, 2, 959-965

[31] High-Performance Stretchable Photodetector based on CH3NH3PbI3     Microwires and Graphene, Nanoscale, 2018, 10, 10538–10544

[32] High-Performance, Ultra-broadband, Ultraviolet to Terahertz Photodetectors     based on Suspended Carbon Nanotube Films, ACS Applied Materials &     Interfaces, 2018, 10, 36304−36311

[33] Broadband Photoresponse Based on A Synergetic Effect of Surface Ions and Plasmon Polaritons, Journal of Materials Chemistry C, 2018, 6, 1199--1205

[34] Formic Acid: An Accelerator and Quality Promoter     for Nonseeded Growth of CH3NH3PbI3 Single     Crystals, Chemical Communications, 2018, 54,     1049-1052

[35] A universal top-down approach toward thickness-controllable perovskite     single-crystalline thin films, Journal of     Materials Chemistry C, 2018, 6, 4464--4470

[36] Nanosecond-Response Speed Sensor Based on Perovskite Single Crystal     Photodetector Array, ACS Photonics, 2018, 5,     3172−3178

[37] Ultrasensitive Photodetectors Based on     High-Quality LiInSe₂ Single Crystal, Journal of Materials     Chemistry C, 2018, 6(46), 12615-12622

[38] Enhanced Broadband Photoresponse of Substrate-free Reduced Graphene Oxide     Photodetectors, RSC Advances, 2017, 7 (74), 46536-46544

[39] Fully Suspended Reduced Graphene Oxide Photodetector with Annealing     Temperature-dependent Broad Spectral Binary Photoresponses, ACS     Photonics, 2017, 4, 2797-2806

[40] Enhanced Photoelectric Performance of Composite Nanostructures Combining     Monolayer Graphene and a RbAg4I5 Film, Applied     Physics Letters, 2017, 110: 213106

[41] An     Origami Perovskite Photodetector with Spatial Recognition Ability, ACS     Applied Materials & Interfaces, 2017, 9(12): 10921-10928

[42] Free-Standing Reduced Graphene Oxide Thin Films with Ultra-High Carrier     Mobility for Fast Photoelectric Devices, Carbon, 2017, 115:     561-570

[43] Self-Powered Ultra-broadband Photodetector Monolithically Integrated on a     PMN-PT Ferroelectric Single Crystal, ACS Applied Materials & Interfaces,     2016, 8 (48): 32934–32939

[44] Terahertz-induced photothermoelectric response in graphene-metal contact     structures, J. Phys. D: Appl. Phys. 2016, 49: 425101

[45] Perovskite     CH3NH3PbI3(Cl) Single Crystals: Rapid     Solution Growth, Unparalleled Crystalline Quality, and Low Trap Density     toward 108 cm–3, Journal of the American Chemical     Society, 2016, 138: 9409-9412

[46] Rapid, controllable growth of silver nanostructured     surface-enhanced Raman scattering substrates for red blood cell detection, Scientific     Reports, 2016, 6: 24503

[47] A self-powered photodetector based on CH3NH3PbI3 single     crystal with asymmetric electrodes, Cryst. Eng. Comm., 2016, 18:     4405–4411

[48] High-stability Organic Red-light Photodetector for Narrowband Applications,     Laser     & Photonics Reviews, 2016, 10(3): 473–480

[49] High-Performance     Planar-Type Photodetector on (100) Facet of MAPbI3 Single     Crystal, Scientific Reports2015, 5: 16563

[50] Terahertz photodetector     based on double-walled carbon nanotube macrobundle–metal contacts, Optics     Express, 2015, 23(10): 13348-13357

[51] Dynamic and Atomic-Scale     Understanding of the Twin Thickness Effect on Dislocation Nucleation and     Propagation Activities by in situ Bending of Ni Nanowires, Acta     Materialia, 2015, 90:     194–203

[52] Self-powered ultrafast     broadband photodetector based on p-n heterojunctions of CuO/Si nanowire     array, ACS Applied Materials & Interfaces. 2014, 6(23): 20887−20894

[53] Electron transport in     carbon nanotube/RbAg4I5 film composite nanostructures     modulated by optical field, Applied Physics Letters, 2014,     104: 243111

[54] Nanowires: Synthesis, Electrical Properties and     Uses in Biological—“Rough     Silver Nanowire, Nanobud and Nanoparticle Substrates: Preparation,     Properties and Use in the SERS Detection of Biomacromolecules”, Nova     Science Publishers, 2014, Chapter 2, pp. 59-88, ISBN:     978-1-63117-855-9

[55] Effect of microwave     irradiation on carbon nanotube fibers: exfoliation, structural change and     strong light emission, RSC Advances, 2014, 4(30): 15502-15506

[56] Photocurrent response of     carbon nanotube–metal heterojunctions in the terahertz range, Optics     Express, 2014, 22(5):     5895

[57] Ultra-Broadband     Photodetector for the Visible to Terahertz Range by Self-Assembling Reduced     Graphene Oxide-Silicon Nanowire Array Heterojunctions, small, 2014, 10(12): 2345–2351

[58] Ion-modulated nonlinear electronic transport in carbon nanotube bundle/RbAg4I5     thin film composite nanostructures, Journal of Applied Physics,     2014, 115: 044302

[59] Solution synthesis of Cu2O/Si     radial nanowire array heterojunctions for broadband photodetectors, Materials     Research Express, 2014, 1(1):     015002

[60] Significantly enhanced     photoresponse in carbon nanotube film/TiO2 nanotube array     heterojunctions by pre-electroforming, Nanotechnology, 2013, 24(46): 465203

[61] In situ atomic-scale     observation of continuous and reversible lattice deformation beyond the     elastic limit, Nature Communications, 2013, 4: 2413

[62] Noninvasive three-dimensional live imaging     methodology for the spindles at meiosis and mitosis, Journal of Biomedical Optics     2013, 18(5): 050505

[63] Significantly enhanced thermoelectric properties of ultralong double-walled     carbon nanotube bundle, Applied Physics Letters, 2013,102(5): 053105

[64] Fabrication     of copper nanowires by a solid-state ionics method and their surface     enhanced Raman scattering effect, Materials Letters, 2013, 92:     143-146

[65] Understanding three-dimensional spatial relationship     between the mouse second polar body and first cleavage plane with     full-field optical coherence tomography, Journal of Biomedical Optics,     2013, 18(1): 010503

[66] Negative and positive photoconductivity modulated by     light wavelengths in carbon nanotube film, Applied Physics Letters,     2012, 101, 123117

[67] Label-free subcellular 3D live imaging of     preimplantation mouse embryos with full-field optical coherence tomography,     Journal of Biomedical Optics, 2012, 17(7): 070503

[68] The     wavelength dependent photovoltaic effects caused by two different     mechanisms in carbon nanotube film/CuO nanowire array heterodimensional     contacts, Applied Physics Letters, 2012, 100: 251113

[69] Fabrication of double-walled carbon nanotube film/Cu2O     nanoparticle film/TiO2 nanotube array heterojunctions for     photosensors, Applied Physics Letters, 2012, 100,     253113

[70] High magnetic field annealing effect on visible     photoluminescence enhancement of TiO2 nanotube arrays, Applied     Physics Letters, 2012, 100: 043106

[71] Fabrication of high performance surface enhanced Raman scattering     substrates by a solid-state ionics method. Nanotechnology,     2012, 23: 125705

[72] Novel photodetectors based on double-walled carbon     nanotube film/TiO2 nanotube array heterodimensional contacts, Nano     Research, 2011, 4(9): 901-907

[73] Fabrication     of carbon nanotube/silicon nanowire array heterojunctions and their silicon     nanowire length dependent photoresponses, Chemical     Physics Letters, 2011, 501: 461-465

[74] Fabrication and photoconductivity of macroscopically     long coaxial structured Ag/Ag2S nanowires with different     core-to-shell thickness ratios, Nanotechnology, 2011, 22,     035202

[75] Negative     photoconductivity induced by surface plasmon polaritons in Ag nanowire     macrobundles, Optics Express, 2010, 18(5): 4066-4073

[76] Metal-insulator transition in Au-NiO-Ni dual schottky nanojunctions, Nanotechnology,     2009, 20: 455203

[77] Fabrication of oriented arrays of porous gold microsheaths using     aligned silver nanowires as sacrificial template, Materials Letters, 2009, 63: 148-150

[78] Field-induced semiconductor-metal transition in     individual NiO–Ni Schottky nanojunction, Applied Physics Letters,     2008, 93: 152107

[79] Disordered multiwalled carbon nanotube mat for light spot position     detecting Applied Physics A, 2008, 91: 229-233

[80] The prominent photoinduced voltage effect of     as-prepared macroscopically long Ag core/Ni shell nanoheterojunctions Nanotechnology,     2008, 19: 085703

[81] Nanotechnology Research: New Nanostructures,     Nanotubes and Nanofibers—“Macroscopic-long     metal nanostructures and corresponding metal chalcogenide semiconductors”, Nova     Science Publishers, 2008, Chapter 9, pp.291-321, ISBN:     978-1-60021-902-3

[82] Thermo- and photoinduced voltages in Ag     heterodimensional junctions, Applied Physics Letters, 2007, 91(16):     161107

[83] Oxidized macroscopic-long Cu nanowire     bundle photoconductor, Applied Physics Letters, 2007, 90:     201119

[84] Carbon nanotube     macrobundles for light sensing Small, 2006, 2: 988-993

[85] A technique for controlling the alignment     of silver nanowires with an electric field Nanotechnology,     2006, 17: 2378-2380

[86] Photoinduced currents in carbon nanotube / metal heterojunctions Applied     Physics Letters, 2006, 88: 131107

[87] Shape-controlled synthesis of silver nanostructures Nanotechnology,     2005, 16: 2412-2414

[88] Synthesis of copper nanowires under a direct current electric field Nanotechnology,     2005, 16: 2030-2032

[89] The     effect of an electric field on the phase separation of Ag-doped glass, Materials Science &     Engineering A,     2004, 367: 272-276

[90] Polarized incandescent     light emission from carbon nanotubes, Applied Physics Letters, 2003,     82 (11): 1763-1765

[91] First overtone frequency stimulated quartz tuning fork used for     shear-force scanning near-field optical microscopy, Chinese     Physics Letters, 2003, 20(11):     1928-1931

[92] Observation of the     in-vivo reporter of green fluorescent protein in a plant root by scanning     near-field optical microscopy, Chinese Physics Letters, 2002,     19: 1389-1391

[93] Fabrication and     application of near-field optical fiber probe, Chinese Physics,     2001, 10(7): 631-635

[94] Fabrication of large     cone angle optical fiber probe by dynamic chemical etching methodActa Physica Sinica200150(12):     2382-2386

[95] Екситоннi спектри потрiйних сполук Ме2AgI3, УФЖ.,     1996, 41(4): 471-474

[96] Низкочастотный оптический спектр тройных соединений     CsCu2I3 и CsAg2I3, ФТТ., 1996, 38(10): 3005-3011

[97] Оптические     спектры и экситоны в тройных соединенияхCs2AgI3 и CsAg2I3, Опт. и Спектр., 1996, 80(4): 643-647

[98] Оптический спектр и экситоны     в суперионном проводнике KAg4I5, Функциональные материалы, 1995, 2(4):     438-444

[99] Оптические спектры и     экситоны в тройных соединениях системы (RbI)1-X(CuI)X, Опт. и     Спектр., 1995,78(3): 436-440

[100] Exciton spectrum in superionic RbAg4I5     condoctor, Func. Mater., 1994, 1(1), 51-55