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Peer reviewed papers (SCI/SCIE)

  1. "Stable and scalable large-area InP quantum dot light-emitting diodes using ZnMgO with a convenient NH4Cl surface treatment", under review

  2. "Top-emitting QLEDs with Thin Stabilizing Layer for Uniform Silver Electrodes", under review

  3. "Broadband Neuromorphic Phototransistors Based on Oxygen Vacancy Modulation in Indium-Gallium-Zinc Oxide Films", under revision

  4. H. Jeong, J. Park and J. Kim*, "Surface engineering of SnO2 nanoparticles as electron transport layers for efficient quantum dot light-emitting diodes", Journal of the Korean Ceramic Society, 62, p988, 2025

  5. S. Kim and J. Kim*, "Highly efficient green InP/ZnSe/ZnS quantum dots synthesized using tris(diethylamino)phosphine", Journal of Information Display, 26, p257, 2025

  6. S. Oh, J. Choi, J. Park, Y. K. Choi, T. Park, A. Ali, J. Ahnm, J. Kim*, S. J. Oh*, "Surface Passivation Engineering for Stable Optoelectronic Devices via Hydroxyl-Free ZnMgO Nanoparticles", Nano Convergence 12, p28, 2025

  7. B. Kim and J. Kim*, "Large-area quantum dot light-emitting diodes employing sputtered Zn0.85Mg0.15O as the electron transport material", Electronic Materials Letters 20, p1402024

  8. S. Y. Lee, D. Chae, J. Kim, S. Oh, J. Kim*, H. Lee*, S. J. Oh*, "Smart Building Block with Colored Radiative Cooling Devices and Quantum Dot Light Emitting Diodes", Nanoscale 16, p1664, 2024 (Co-corresponding)

  9. H. Im, J. Kim, J. Kim*, S. Kim*, "Scalable Bilayer MoS2-based Vertically Inverted p-i-n Light-Emitting Diodes", Advanced Materials Interfaces 11, p2300319, 2024 (Co-corresponding)

  10. Y-H. Kim, S-K. Yoon, Y-J. Lee, D-Y. Kim, H-Y. Kim, Y. Kim, S. M. Park, G. M. Park, Y. Kim, J. Kim*, H. Yang*, "Compositional, Heterostructural Tuning in Red-Emissive Ternary ZnSeTe Quantum Dots for Display Application", ACS Applied Nano Materials 6, p19947, 2023 (Co-corresponding)

  11. H. Kim, T. Kim, Y. Kang, S.P. Jeon, J. Kim, J. Kim, S.K. Park*, Y-H. Kim*, "Sub-volt metal-oxide thin-film transistors enabled by solution-processed high-k Gd-doped HfO2 dielectric films", Materials Science in Semiconductor Processing 166, p107746, 2023

  12. J. Kim and J. Kim*, "Structural and optical properties of NiO/ZnS core-shell nanostructures for efficient quantum dot light-emitting diodes", Materials 16, p5106, 2023

  13. C. Yoon and J. Kim*, "Stable quantum dot light-emitting diodes employing TiO2 nanoparticles as a mixed emission layer", Korean Journal of Metals and Materials, 61, p33, 2023

  14. J.H. Bae, S. Kim, J. Ahn, C. Shin, B.K. Jung, Y.K. Hong, W. Kim, D.H. Ha, T. Ng, J. Kim*, S.J. Oh*, “Acid-Base Reaction Assisted Quantum Dot Patterning via Ligand Engineering and photolithography”, ACS Applied Materials & Interfaces 14p47831, 2022 (Co-corresponding)

  15. C. Yoon, A. Moon, H. Yang*, and J. Kim*, "Highly efficient electroluminescence devices with a mixed layer of SnO2 and colloidal quantum dots", Journal of Information Display 23, p193, 2022

  16. M. Kang and J. Kim*, "A study on the ZnO thin film deposited by RF sputtering method as an electron transport layer in quantum dot light-emitting diodes", Korean Journal of Metals and Materials 59, p718, 2021

  17. M. Kim, S. Oh, S. Song, J. Kim*, Y.-H. Kim*, "Solution-Processed Memristor Devices Using a Colloidal Quantum Dot-Polymer Composite", Applied Sciences 11, p5020, 2021 (Co-corresponding)

  18. M. Kim and J. Kim*, "A Study on the stability of TiO2 nanoparticles as an electron transport layer in quantum dot light-emitting diodes", Korean Journal of Metals and Materials 59, p476, 2021

  19. S. Lee, Y. Kim, and J. Kim*, "Solution-processed NiO as a hole injection layer for stable quantum dot light-emitting diodes", Applied Sciences 11, p4422, 2021

  20. M. Kim, N. Lee, J. H. Yang, C. W. Han, C-Y Han, W. Han, H-H Park, H. Yang*, and J. Kim*, "High-efficiency quantum dots light-emitting diodes based on Li-doped TiO2 nanoparticles as an alternative electron transport layer", Nanoscale 13, p2838, 2021

  21. H. Woo, J. Kim, and S. Kang*, "Study of anti-glare pattern forming process by glass etching for improved image quality", Journal of Nanoscience and Nanotechnology 21, p1937, 2021

  22. W. Han, S. Oh, C. Lee, J. Kim, and H.H. Park*, "ZnO Nanocrystal Thin Films for Quantum-Dot Light-Emitting Devices", ACS Applied Nano Materials 3, p7535, 2020

  23. S.E. Ju, C. G. Yoon, and J. Kim*, "Hybrid electroluminescence devices with solution- processed mixed emitting layers of red quantum dots and blue small molecules", Coatings 10, p645, 2020

  24. W. Han, J. Kim*, and H-H. Park*, "Dielectric properties of BaTiO3 nanocrystals synthesized by ambient-condition-sol process at low temperature", Journal of the Korean Ceramic Society 57, p213, 2020 (Co-corresponding)

  25. S. Oh and J. Kim*, "Correlation between the morphology of ZnO layers and the electroluminescence of quantum dot light-emitting diodes", Applied Sciences 9, p4539, 2019

  26. A. Moon and J. Kim*, "Hybrid quantum dot light-emitting diodes for white emission using blue phosphorescent organic molecules and red quantum dots," Micromachines 10, p609, 2019

  27. W. Han, J. Kim, and H.H. Park*, "An evaluation of fluorinated titanium oxide nanocrystals with UV exposure treatment for oxygen vacancy control," Applied Surface Science 489, p824, 2019

  28. S. Oh, C-Y Han, H. Yang* and J. Kim*, "Highly efficient white electroluminescent devices with hybrid double emitting layers of quantum dots and phosphorescent molecules," Nanoscale 11, p9276, 2019

  29. W. Han, J. Kim*, and H.H. Park*, "Control of electrical conductivity of highly stacked zinc oxide nanocrystals by ultraviolet treatment," Scientific Reports 9, p6244, 2019 (Co-corresponding)

  30. S.E. Ju and J. Kim*, "Quantum dot light-emitting diodes employing phosphorescent organic molecules as double emission layers," Electronic Materials Letters 15, p363, 2019

  31. J. Kim and J. Kim*, "Effect of gold nanoparticles on the performance of quantum dot light-emitting diodes," Nanoscience and Nanotechnology Letters 10, p1429, 2018 

  32. H. Lee and J. Kim*, "Optical properties of ZnO/Al/Ag/ZnO multilayers as near IR cut-off filters," Journal of the Korean Physical Society 73, p858, 2018

  33. M-H Hong, H. Choi, D.I. Shim, H.H. Cho, J. Kim, and H.H. Park*, "Study of the effect of stress/strain of mesoporous Al-doped ZnO thin films on thermoelectric properties," Solid State Science 82, p84, 2018

  34. K. Lee, Y-H Kim, J. Kim, and M.S. Oh*, "Transparent and flexible ZTO TFTs and inverters using low-pressure oxygen annealing process,", Journal of the Korean Physical Society 72, p1073, 2018

  35. J. Kim and J. Kim*, "Enhancement of green quantum dot light-emitting diodes with Au NPs in the hole injection layer," International Journal of Nanotechnology 15, p485, 2018

  36. E-P Jang, J-H Jo, M-S Kim, S-Y Yoon, S-W Lim, J. Kim*, and H. Yang*, "Near-complete photoluminescence retention andimproved stability of InP quantum dots after silica embedding for their application to on-chip-packaged light-emitting diodes," RSC Advances 8, p10057, 2018 (Co-corresponding)

  37. H. Lee and J. Kim*, "Micro-Cavity Effect of ZnO/Ag/ZnO Multilayers on Green Quantum Dot Light-Emitting Diodes", Journal of the Korean Ceramic Society 55, p174, 2018

  38. C-Y Han, K-H Lee, M-S Kim, J-W Shin, J.S. Kim, J-H Hwang, T. Kim, M.S. Oh, J. Kim, Y.R. Do, and H. Yang*, "Solution-processed fabrication of highly transparent mono- and tricolored quantum dot-light-emitting diodes," Organic Electronics 45, p145, 2017

  39. W. Lee, J. Kim, and Y-H Kim*, "High-performance InOx/GaOx bilayer channel thin-film transistors made using persistent high-surface-energy induced by photochemical activation," Journal of Alloys and Compounds 723, p627, 2017

  40. K. Lee, Y-H Kim, S-M Yoon, J. Kim*, and M.S. Oh*, "Effects of channel thickness on oxide thin film transistor with double-stacked channel layer," Journal of the Korean Physical Society 71, p561, 2017 (Co-corresponding)

  41. J-W Kim and J. Kim*, “Flexible InP based quantum dot light-emitting diodes using Ag nanowire-colorless polyimide composite electrode,” Journal of Vacuum Science and Technology B 35, p04E101, 2017

  42. H.Y. Kim, Y.J. Park, J. Kim, C. J. Han, J. Lee, Y. Kim, T. Greco, C. Ippen, A. Wedel, B-K Ju, and M.S. Oh*, "Transparent InP quantum dot light-emitting diodes with ZrO2 electron transport layer and Indium Zinc Oxide top electrode," Advanced Functional Materials 26, p3454, 2016

  43. D-G Kim, J. Kim, S-B Jung, Y-S Kim, and J-W Kim*, "Electrically and mechanically enhanced Ag nanowires-colorless polyimide composite electrode for flexible capacitive sensor," Applied Surface Science 380, p223, 2016

  44. ​I. Jang+, J. Kim+, C. Ippen, T. Greco, M.S. Oh, J. Lee, W.K. Kim, A. Wedel, C.J. Han, and S.K. Park, “Study of ethanolamine surface treatment on the metal-oxide electron transport layer in Inverted InP quantum dot light-emitting diodes,” Electronic Materials Letters 11, p1066, 2015 (+ equally contributed to this paper)

  45. ​C. Ippen, T. Greco, Y. Kim, C. Pries, J. Kim, M.S. Oh, C.J. Han, and A. Wedel*, “Color tuning of indium phosphide quantum dots for cadmium-free quantum dot light-emitting devices with high efficiency and color saturation,” Journal of the Society for Information Display 23, p285, 2015

  46. K-H Ok+, J. Kim+, S-R Park, Y. Kim, C-J Lee, S-J Hong, M-G Kwak, N. Kim, C.J. Han, and J-W Kim, “Ultra-thin and smooth transparent electrode for flexible and leakage-free organic light-emitting diodes,” Scientific Reports 5, p9464, 2015  (+ equally contributed to this paper)

  47. J-W Jo, J. Kim, K-T Kim, J-G Kang, M-G Kim, K-H Kim, H. Ko, J. Kim, Y-H Kim, and S.K. Park*, “Highly stable and imperceptible electronics utilizing photo-activated heterogeneous sol-gel metal-oxide dielectrics and semiconductors,” Advanced Materials 27, p1182, 2015

  48. J-H Kim, C-Y Han, K-H Lee, K-S An, W. Song, J. Kim. M.S. Oh, Y.R. Do, and H. Yang*, “Performance Improvement of Quantum Dot-Light-Emitting Diodes Enabled by Alloyed ZnMgO Nanoparticle Electron Transport Layer,” Chemistry of Materials 27, p197, 2015

  49. J. Kwon, Y.K. Hong, H-J Kwon, Y.J. Park, B.W. Yoo, J. Kim, C.P. Grigoropoulos, M.S. Oh, and S. Kim*, “Optically Transparent Thin-Film Transistors based on 2D multilayer MoS2 and Indium Zinc Oxide Electrodes,” Nanotechnology 26, p035202, 2015

  50.  I. Jang+, J. Kim+, C. Ippen, T. Greco, M.S. Oh, J. Lee, W.K. Kim, A. Wedel, C.J. Han, and S.K. Park*, “Inverted InP quantum dot light-emitting diodes using low-temperature solution-processed metal-oxide as an electron transport layer,” Japanese Journal of Applied Physics, 54, p02BC01, 2015 (+ equally contributed to this paper)

  51. C.H. Jo, J.H. Kim, J. Kim, J. Kim, M.S. Oh, M.S. Kang, M-G Kim, Y-H Kim, B-K Ju, and S.K. Park*, “Low-temperature annealed PbS quantum dot devices for scalable ultra-flexible ambipolar thin-film-transistors and circuits,” Journal of Materials Chemistry C 2, p10305, 2014

  52. S. Lim, Y. Kim, J. Lee, C.J. Han, J. Kang, and J. Kim*, “Investigation of colloidal PbS quatum dot-based solar cells with near infrared emission,” Journal of Nanoscience and Nanotechnology 14, p9346, 2014

  53. Y. Kim, C. Ippen, T. Greco, A. Wedel, M.S. Oh, C.J. Han, and J. Kim*, “Semitransparent quantum dot light-emitting diodes by cadmium-free colloidal quantum dot,” Journal of Nanoscience and Nanotechnology 14, p8636, 2014

  54. Y. Kim, C. Ippen, T. Greco, A. Wedel, J. Lee, M.S. Oh, C.J. Han, and J. Kim*, “Increased shell thickness in InP multishell quantum dots leading to efficiency and stability enhancement in light-emitting diodes,” Optical Materials Express 4, p1436, 2014

  55. W-O Seo, Y. Jung, J. Kim, D. Kim, and J. Kim*, “Chemical bath deposition of CdS on grapheme-coated flexible glass substrate,” Applied Physics Letters 104, p133902, 2014

  56. Y. Kim, C. Ippen, T. Greco, A. Wedel, I. Jang, S. Park, M.S. Oh, C.J. Han, J. Lee, and J. Kim*, “Electrical aging effect of ZnS based quantum dots for white light-emitting diodes,” Electronic Materials Letters 10, p479, 2014

  57. S. Oh, H. Park, Y. Jung, J. Kim, M.S. Oh, and J. Kim*, “Selective deposition of grapheme sheets on a flexible substrate by a nonuniform electric filed,” Journal of Vacuum Science and Technology B 32, p020602, 2014

  58. C. Ippen, T. Greco, Y. Kim, J. Kim, M. S. Oh, C.J. Han, and A. Wedel*, “ZnSe/ZnS quantum dots as emitting material in blue QD-LEDs with narrow emission peak and wavelength tenability,” Organic Electronics 15, p126, 2014

  59.  J. Kim, Y.J. Park, Y. Kim, J.I. Han, Y-H Kim, C.J. Han, and M.S. Oh*, “Effect of oxide electron transport layer on quantum dots light emitting diode with organic/inorganic hybrid structure,” Electronic Materials Letters 9, p779, 2013

  60. Y. Kim, T. Greco, C. Ippen, A. Wedel, M. S. Oh, C. J. Han, and J. Kim*, “Indium phosphide-based colloidal quantum dot light-emitting diodes on flexible substrate,” Nanoscience and Nanotechnology Letters 5, p1065, 2013

  61. Y.J. Kim, S.T. Ha, G.J. Lee, J.H. Nam, I.H. Ryu, S.H. Nam, C.M. Park, I. In, J. Kim, and C.J. Han*, “Investigation of space charge distribution of LDPE/GO (Graphene oxide) nanocomposite for HVDC application,” Journal of Nanoscience and Nanotechnology 13, p3464, 2013

  62. Y-H Kim, J-S Heo, T-H Kim, S. Park, M-H Yoon, J. Kim, M.S. Oh, G-R Yi, Y-Y Noh, and S.K. Park*, “Flexible metal-oxide devices made by room-temperature photochemical activation of sol-gel films,” Nature 489, p128, 2012

  63. Y. Jung, X. Wang, J. Kim, S.H. Kim, F. Ren, S.J. Pearton, and J. Kim*, “GaN-based light-emitting diodes on origami substrates,” Applied Physics Letters 100, p231113, 2012

  64. S. Thongpang, T.J. Richner, S.K. Brodnick, A. Schendel, J. Kim, J.A. Wilson, J. Hippensteel, L. K-Higby, D. Moran, A.S. Ahmed, D. Neimann, K. Sillay, and J.C. Williams*, “A micro-electrocorticography platform and deployment strategies for chronic BCI applications,” Clinical EEG and Neuroscience 42, p259, 2011

  65. S.J. Oh, C.J. Han, J. Kim, Y-H Kim, S.K. Park, J-I Han, J.W. Kang and M.S. Oh*, “Improving the electrical properties of Zinc Tin Oxide thin film transistors using atmospheric plasma treatment,” Electrochemical and Solid-State Letters 14, pH354, 2011

  66. J. Kim, T.J. Richner, S. Thongpang, K.A. Sillay, D.B. Niemann, A.S. Ahmed. L. K-Higby, and J.C. Williams*, “Flexible thin film electrode arrays for minimally invasive neurological monitoring,” Proceedings of the 31st Annual International Conference of IEEE EMBS, p5506, 2009

  67. J. Kim, J.A. Wilson, and J.C. Williams*, “A cortical recording platform utilizing uECoG electrode arrays,” Proceedings of the 29th Annual International Conference of IEEE EMBS, p5353, 2007

  68. J. Kim and J.C. Williams*, “Rapid prototyping of patterned poly-l-lysine microstructures,” Proceedings of the 28th Annual International Conference of IEEE EMBS, p2110, 2006

  69. C.Y. Rha, W.S. Kim, J. Kim, and H.H. Park*, “Relationship between microstructure and electrochemical characteristics in steel corrosion,” Applied Surface Science 169-170, p587, 2001

  70. M.G. Kang, J. Kim, and H.H. Park*, “Amelioration of the interfacial properties in Au/GaAs schottky contact using sulfidation and hydrogenation,” Japanese Journal of Applied Physics 39, p7003, 2000

  71. W.S. Kim, J. Kim, H.H. Park, and H.N. Lee*, “Fabrication and characterization of Pt-oxide electrode for FRAM application,” Japanese Journal of Applied Physics 39, p7097, 2000 

  72. J. Kim, M.G. Kang, and H.H. Par*k, “Investigation on the surface characteristics of GaAs after Sulfuric-Vapor Treatment,” Thin Solid Films 355, p423, 1999

  73. J. Kim, M.G. Kang, and H.H. Park*, “Distribution of S in (NH4)2Sx treated GaAs surface,” Journal of the Korean Physical Society 35, p152, 1999

  74. J. Kim, S.H. Sa, M.G. Kang, and H.H. Park*, “A study on the structural distribution of Se passivated GaAs surfaces,” Thin Solid Films 332, p305, 1998

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