Achieving high brightness of Si LED via a field effect approach,Appl. Phys. Lett. 104, 061105(2014)
Surface plasmons on Ag clusters induced via ultrasonic and thermal treatments and their enhancement of Si light emission,Physica E 64, 63-67(2014)
Mass production of Si quantum dots for c-Si solar cell efficiency improvement,Mater. Lett. 133, 80-82(2014)
Enhancing the brightness of Si nanocrystal light emitting device with electro-excited surface plasmons,Nanotechnology 25, 355203(2014)
Enhancing optical gains in Si nanocrystals with hydrogenation and cerium doping,J. Appl. Phys. 116, 043512(2014)
Effects of crystallographic surface and co-sputtered atom on the growth of ion-sputter induced Si nanocone arrays,Appl. Phys. A 119, 1033-1038(2015)
A synergetic effect of surface texture and field passivations on improving Si solar cell performance,Physica E 71, 96-100(2015)
Enhancing photocatalysis in SrTiO3 by using Ag nanoparticles: A two-step excitation model for surface plasmon-enhanced photocatalysis,J. Chem. Phys. 143, 084706(2015)
White light emissions and optical gains from a Si nanocrystal thin film,Nanotechnology 26, 475203(2015)
A synergetic application of surface plasmon and field effect to improve Si solar cell performance,Nanotechnology 27, 145203(2016)
A porous Si emitter crystalline-Si solar cell with 18.97% efficiency s,Nanotechnology 27, 425207(2016)
High Fill Factors of Si Solar Cells Achieved by Using an Inverse Connection Between MOS and PN Junctions,Nanoscale Res. Lett. 11, 453(2016)
A Synergetic Effect of Surface Plasmon and Ammoniation on the Enhanced Photocatalytic Activity of ZnO Nanorods,RSC Advances 6, 97808-97817(2016)
Light emissions from a Si crystalline thin film prepared by HSQ,Physica E 89, 57-60(2017)
Enhancing the ultraviolet-visible-near infrared photovoltaic responses of crystalline-silicon solar cell by using aluminum nanoparticles,Physica E 94, 174-177(2017)
An Investigation on a Crystalline-Silicon Solar Cell with Black Silicon Layer at the Rear,Nanoscale Research Letters, 12, 623(2017)
An all-silicon laser based on silicon nanocrystals with high optical gains,Science Bulletin 63(2)75-77 (2018)
A Synergetic Effect of Ytterbium-doping and Ammoniation on Enhancing UV and visible Photocatalytic Activities of TiO2,Chemical Physics Letters, 2018, 64C: 53-59.
Black silicon Schottky photodetector in sub-bandgap near-infrared regime,Optics Express 27(3), 3161-3168(2019)
Emission characteristics and wavelength tunability of all-silicon distributed feedback lasers,IEEE JSTQE 26(2), 1500107(1-7)(2020)
All-Inorganic Silicon White Light-Emitting Device with an External Quantum Efficiency of 1.0%,Opt. Express 28, 194(2020). (该工作被Laser Focus World作专题报导,J. Wallace, Laser Focus World 56, 31(2020))
High-pressure hydrogenation induced light emission enhancement of Si nanocrystals,Opt. Express 28, 23320-23328(2020)
Improving the performance of crystalline Si solar cell by high-pressure hydrogenation,Chinese Phys. B Vol. 29, No. 11 (2020) 118801
High-pressure Ar passivation to enhance the photoluminescence of Si nanocrystals, Physics E 131, 114680(2021).
High brightness silicon nanocrystal white light-emitting diode with luminance of 2060 cd/m2, Optics Express 29, 34126-34134(2021). (该工作被Semiconductor Today作专题报导, M. Cooke, Semiconductor Today, October (2021)。它是当时最高亮度的硅LED——此结论见:L. Pavesi, “Thirty Years in Silicon Photonics: A Personal View”, Frontiers in Physics 9, 786028 (December 2021))
Achieving high-responsivity near-infrared detection at room temperature by nano-Schottky junction arrays via a black silicon/platinum contact approach, Photonics Research 9, 1324-1329(2021).
Dispersed freestanding silicon nanocrystals for Si white light-emitting diode, Chemical Physics Letters 785, 139155(2021).
A synergistic approach of interface engineering to improve the performance of silicon nanocrystal light-emitting diode, Vacuum 197, 110822(2022).
Observation of waveguide Fabry-Perot lasing in highly efficient Si nanocrystals, Results in Physics 34, 105336 (2022).
Sub-bandgap near-infrared photovoltaic response in Au/Al2O3/n-Si metal–insulator–semiconductor structure by plasmon-enhanced internal photoemission, Discover Nano, 18(2023): 33.
A Silicon Sub-Bandgap Near-Infrared Photodetector with High Detectivity Based on Textured Si/Au Nanoparticle Schottky Junctions Covered with Graphene Film, Sensors, 23(2023): 6184.