Peer Reviewed Journals
Peer Reviewed Journals
* and ^ denote equal contribution of the first and corresponding authors, respectively.
71) A. Choi*, Y.‐Y. Song*, J. Kim, D. Kim, M.‐H. Kim, S. W. Lee^, D.‐H. Seo^, H.‐W. Lee^, "Enhancing Efficiency of Low‐Grade Heat Harvesting by Structural Vibration Entropy in Thermally Regenerative Electrochemical Cycles,"
Advanced Materials, DOI: 10.1002/adma.202303199.
70) J.‐E. Jang, R.‐a. Kim, S. Jayasubramaniyan, C. Lee, J. Choi, Y. Lee, S. Kang, J. Ryu, S. W. Lee, J. Cho, D. W. Lee, H.‐K. Song, W. Choe, D.‐H. Seo, H.‐W. Lee, "Full‐Hexacyanometallate Aqueous Redox Flow Batteries Exceeding 1.5 V in an Aqueous Solution,"
Advanced Energy Materials, DOI: 10.1002/aenm.202300707.
69) J. Li, X. Li, D. Lee, J. Yun, A. Wu, C. Jiang, and S. W. Lee, "Engineering of Solvation Entropy by Poly(4-styrenesulfonic acid) additive in Aqueous Electrochemical System for Enhanced Low-Grade Heat Harvesting,"
Nano Letters, 23, 6164-6170, 2023.
68) Z. Li, J. Yun, X. Li, M. Kim, J. Li, D. Lee, A. Wu, and S. W. Lee, "Power-Free Contact Lens for Glucose Sensing,"
Advanced Functional Materials, DOI: 10.1002/adfm.202304647.
67) J. Yun, Z. Li, X. Miao, X. Li, J. Y. Lee, W. Zhao, and S. W. Lee, "A tear-based battery charged by biofuel for smart contact lenses,"
Nano Energy, 110, 108344, 2023.
66) A. Wu, X. Li, D. Lee, J. Li, J. Yun, C. Jiang, Z. Li, and S. W. Lee, "Thermoresponsive Ionic Liquid for Electrochemical Low-grade Heat Harvesting,"
Nano Energy, DOI: 10.1016/j.nanoen.2022.108022.
65) X. Li, A. Wu, C. Gao, Z. Li, and S. W. Lee, "Copper hexacyanoferrate as a long-life cathode for aqueous aluminum ion batteries,"
Materials Today Energy, DOI: 10.1016/j.mtener.2022.101205.
64) J. Li*, P. Yang*, X. Li, C. Jiang, J. Yun, W. Yan, K. Liu, H. J. Fan^, and S. W. Lee^, "Ultrathin Smart Energy-Storage Devices for Skin-Interfaced Wearable Electronics,"
ACS Energy Letters, 8, 1–8, 2023.
https://doi.org/10.1021/acsenergylett.2c02029
63) Y. Kim, S. J. Yeom, J. Yoo, J. Yun, H.-W. Lee, S. W. Lee, "Temperature-dependent fracture resistance of silicon nanopillars during electrochemical lithiation,"
Nano Letters, 22, 16, 6631-6636 (2022).
https://doi.org/10.1021/acs.nanolett.2c01946
62) X. Li, C. Gao, J. Yun, Y. Kim, M. Kim, J. Li, and S. W. Lee, "Continuous thermally regenerative electrochemical cycle for low grade heat harvesting,”
Nano Energy, 101, 107547 (2022).
61) S. Ko, M.-J. Baek, T.-U. Wi, J. Kim, C. Park, D. Lim, S. J. Yeom, K. Bayramova, H. Y. Lim, S. K. Kwak, S. W. Lee, S. Jin, D. W. Lee, and H.-W. Lee, "Understanding the Role of a Water-Soluble Catechol-Functionalized Binder for Silicon Anodes by Diverse In Situ Analyses,"
ACS Materials Letters, 5, 5, 831-839, 2022
60) Y. Liu, C. Gao, J. Yun, Y. Kim, M. Kim, J. Li, and S. W. Lee, “Thermally Assisted Alkali/Zinc Ion Hybrid Battery for High Roundtrip Efficiency,”
ACS Appl. Energy Mater. 5, 2789-2785 (2022).
59) A. Choi, T. Kim, M.-H. Kim, S. W. Lee, Y. H. Jung, and Hyun-Wook Lee, “Mitigating Jahn–Teller Effects by Fast Electrode Kinetics Inducing Charge Redistribution,”
Advanced Functional Materials, 2111901 (2022).
58) S. J. Yeom, T.-U. Wi, S. Ko, C. Park, K. Bayramova, S. Jin, S. W. Lee, and H.-W. Lee, “Nitrogen Plasma-Assisted Functionalization of Silicon/Graphite Anodes to Enable Fast Kinetics,”
ACS Appl. Mater. Interfaces, 14, 4, 5237-5246 (2022).
57) Y. Liu*, C. Gao**, J. Yun**, Y. Kim**, M. Kim*, J. Li**, S. W. Lee^, “Tuning the Hydration Entropy of Cations during Electrochemical Intercalation for High Thermopower,”
Advanced Energy & Sustainability Research, 202100176 (2022).
56) C. Park, M.-H. Kim, S. Ko, C. Lee, A. Choi, T. Kim, J. Park, D. W. Lee, S. W. Lee, and H.-W. Lee^, “Prussian Blue Nanolayer-Embedded Separator for Selective Segregation of Nickel Dissolution in High Nickel Cathodes,”
Nano Lettters, 22, 4, 1804–1811 (2022).
55) P. Yang*, J. Li*, S. W. Lee^, and H. J. Fan^, “Printed Zinc Paper Batteries,”
Advanced Science, 2103894 (2021).
54) J. Yun, Y. Kim, C. Gao, M. Kim, J. Y. Lee, C.-H. Lee, T.-H. Bae, and S. W. Lee, "Copper Hexacyanoferrate Thin Film Deposition and Its Application to a New Method for Diffusion Coefficient Measurement,"
Nanomaterials, 11, 7, 1860, 2021.
https://doi.org/10.3390/nano11071860
53) N. C. Y. Tham, P. K. Sahoo, Y. Kim, C. Hegde, S. W. Lee, Y.-J. Kim, and V. M. Murukeshan, "Thermally controlled localized porous graphene for integrated graphene-paper electronics,"
Advanced Materials Technologies, 6(5), 2001156 (2021).
https://doi.org/10.1002/admt.202001156
52) J. Yun, Y. Zeng, M. Kim, C. Gao, Y. Kim, L. Lu, T. T.-H. Kim, W. Zhao, T.-H. Bae, S. W. Lee, "Tear based aqueous batteries for smart contact lenses enabled by Prussian blue analogue nanocomposites,"
Nano Letters, 21, 4, 1659-1665 (2021)
https://doi.org/10.1021/acs.nanolett.0c04362
51) C. Gao, Y. Liu, B. Chen, J. Yun, E. Feng, Y. Kim, M. Kim, A. Choi, H.-W. Lee, and S. W. Lee, "Efficient Low-grade Heat Harvesting enabled by Tuning the Hydration Entropy in Electrochemical System,"
Advanced Materials, 33, 13, 2004717 (2021).
[Selected as Front Inside Cover]
50) M. Kim, I. D. Jung, Y. Kim, J. Yun, C. Gao, H.-W. Lee, and S. W. Lee, "An electrochromic alarm system for smart contact lenses,"
Sensors and Actuators: B. Chemical, 322, 128601 (2020).
https://doi.org/10.1016/j.snb.2020.128601
49) X. Yin, L. Wang, Y. Kim, N. Ding, J. Kong, D. Safanama, Y. Zheng, J. Xu, D. V. M. Repaka, K. Hippalgaonkar, S. W. Lee, S. Adams, G. W. Zheng, "Two-dimensional boron nitride for high performance all solid-state Li-S batteries,"
Advanced Science, 7, 19, 2001303 (2020).
https://doi.org/10.1002/advs.202001303
48) I. D. Jung, M. S. Lee, J. Lee, H. Sung, J. Choe, H. J. Son, J. Yun, K.-b. Kim, M. Kim, S. W. Lee, S. Yang, S. K. Moon, K. T. Kim, J.-H. Yu, "Embedding sensors using selective laser melting for self-cognitive metal parts,"
Additive Manufacturing, 33, 101151 (2020).
47) I. D. Jung*, M. Kim*, C. Gao, Y. Liu, C. Park, H.-W. Lee, and S. W. Lee, "Selective Ion Sweeping for Electrochemical Kinetic Energy Harvesting,"
Nano Letters, 20, 1, 1800-1807 (2020).
https://doi.org/10.1021/acs.nanolett.9b05029
46) J. Wang, X. Wang^, S. W. Lee^, and Q. Zhang^, "Enhanced Performance of Electric Double Layer Micro-supercapacitor Based on Novel Carbon Encapsulated Cu Nanowire Network Structure as Electrode,"
ACS Appl. Mater. Interfaces, 11, 40481-40489 (2019).
45) C. Gao, Y. Liu, L. Zheng, E. Feng, S. Sim, Y. Kim, J. Yun, M. Kim, and S. W. Lee, "The Effect of Electrolyte Type on the Li Ion Intercalation in Copper Hexacyanoferrate,"
Journal of the Electrochemical Society, 166, 10, A1732-A1737 (2019).
44) Y. Liu, C. Gao, S. Sim, M. Kim, and S. W. Lee, "Lithium manganese oxide in aqueous electrochemical system for low-grade thermal energy harvesting,"
Chemistry of Materials, 31, 12, 4379-4384 (2019).
[Selected as Supplementary Cover]
43) Y. Kim, S. Sim, S. Kang, J. Yun, H. -W. Lee, and S. W. Lee, "Highly robust silicon bimorph plate anode and its mechanical analysis upon electrochemical lithiation,"
Energy Storage Materials, 23, 292-298 (2019).
42) Y. Kim*, S. Sim*, and S. W. Lee, "Nucleation and growth of lithium-silicon alloy on crystalline silicon,"
Advanced Engineering Materials, 21, 1800520 (2019).
41) C. Gao, Y. Yin, L. Zheng, Y. Liu, S. Sim, Y. He, C. Zhu, Z. Liu, H.-W. Lee, Q. Yuan, and S. W. Lee, "Engineering Electrochemical Temperature Coefficient for Efficient Low-grade Heat Harvesting,"
Advanced Functional Materials, 28, 201803129 (2018).
40) X. Yin, W. Tang, I. D. Jung, K. C. Phua, S. Adams, S. W. Lee, and G. W. Zheng, "Insights into morphological evolution and cycling behaviour of lithium metal anode under mechanical pressure,"
Nano Energy, 50, 659-664 (2018).
39) C. Gao, S. W. Lee^, and Y. Yang^, "Thermally regenerative electrochemical cycle for low-grade heat harvesting,"
ACS Energy Letters, 2, 2326-2334 (2017).
38) W. Liu, S. W. Lee, D. Lin, F. Shi, S. Wang, A. Sendek, and Y. Cui, “Enhancing ionic conductivity in composite polymer electrolyte with well-aligned ceramic nanowire,”
Nature Energy, 2, 17035 (2017).
37) S. Higashi, S. W. Lee, J. S. Lee, K. Takechi, and Y. Cui, "Avoiding short circuits from zinc metal dendrites in anode by backside-plating configuration,"
Nature Communications, 7, 11801 (2016).
36) Z. Zeng*, N. Liu*, Q. Zeng, S. W. Lee, W. L. Mao, and Y. Cui, “In situ measurement of lithiation-induced stress in silicon nanoparticles using micro-Raman spectroscopy,”
Nano Energy, 22, 105-110 (2016).
35) S. W. Lee*, H.-W. Lee*, I. Ryu, H. Gao, W. D. Nix, and Y. Cui, “Kinetics and fracture resistance of lithiated silicon nanostructure pairs controlled by their mechanical interaction,”
Nature Communications, 6, 7533 (2015).
34) X. Zhang, S. W. Lee, H.-W. Lee, Y. Cui, and C. Linder, “A Reaction-Controlled Diffusion Model for the Lithiation of Silicon in Lithium-Ion Batteries,”
Extreme Mechanics Letters, accepted.
33) L. Hanson, W. Zhao, H.-Y. Lou, Z Lin, S. W. Lee, P. Chowdary, Y. Cui, and B. Cui, “Vertical nanopillars for in situ probing of nuclear mechanics in adherent cells,”
Nature Nanotechnology, 10, 554-562 (2015).
32) S. W. Lee, I. Ryu, W. D. Nix, and Y. Cui, “Fracture of crystalline germanium micro pillars during electrochemical lithiation,”
Extreme Mechanics Letters, 2, 15-19 (2015).
31) Y. Yang*, S. W. Lee*, H. Ghasemi, J. Loomis, X. Li, D. Kraemer, G. Zheng, Y. Cui, and G. Chen, “A charging-free electrochemical system for harvesting low-grade thermal energy,”
Proceedings of the National Academy of Sciences U.S.A., 111, 17011-17016 (2014).
30) Y. Yang, J. Loomis, H. Ghasemi, S. W. Lee, J. Wang, Y. Cui, and G. Chen, “A membrane-free battery for harvesting low-grade thermal energy,”
Nano Letters, 14, 6578-6583 (2014).
29) L. A. Berla, S. W. Lee, Y. Cui, and W. D. Nix, “Mechanical behaviour of electrochemically lithiated silicon,”
Journal of Power Sources, 271, 41-51 (2015).
28) H.-W. Lee*, R. Wang*, M. Pasta*, S. W. Lee, N. Liu, and Y. Cui, “Manganese hexacyanomanganate open framework: a high-capacity positive electrode material for Na-ion batteries,”
Nature Communications, 5, 5280 (2014).
27) G. Zheng, S. W. Lee, Z. Liang, H.-W. Lee, K. Yan, H. Yao, H. Wang, W. Li, S. Chu, and Y. Cui, “Interconnected hollow carbon nanospheres for stable lithium metal anodes,”
Nature Nanotechnology, 9, 618-623 (2014).
[Featured in Stanford news etc.]
26) S. W. Lee*, Y. Yang*, H. W. Lee, H. Ghasemi, D. Kraemer, G. Chen, and Y. Cui, “An electrochemical system for harvesting of low-grade heat energy,”
Nature Communications, 5, 3942 (2014).
[Featured in World Changing Ideas 2014 in Scientific American, C&EN, MIT Technology Review, etc.]
25) L. A. Berla*, S. W. Lee*, I. Ryu, Y. Cui, and W. D. Nix, “Robustness of amorphous Si pillar during electrochemical lithiation and delithiation,”
Journal of Power Sources, 258, 253-259 (2014).
24) I. Ryu, S. W. Lee, H. Gao, Y. Cui, and W. D. Nix, “Microscopic model for fracture of crystalline Si nanopillars during lithiation,”
Journal of Power Sources, 255, 274-282 (2014).
23) C. H. Lee, S. W. Lee, and S. S. Lee, “Nanoradio utilizing mechanical resonance of a vertically aligned nanopillar array,”
Nanoscale, 6, 2087-2093 (2014).
22) M. T. McDowell*, S. W. Lee*, W. D. Nix, and Y. Cui, “Understanding of lithiation of silicon and other alloying anode materials for lithium ion battery,”
Advance Materials, 25, 4966-4985 (2013).
21) M. T. McDowell, S. W. Lee, J. Harris, B. Korgel, C. M. Wang, W. D. Nix, and Y. Cui, “In-situ TEM of two-phase lithiation of amorphous silicon nanospheres.”
Nano Letters, 13, 758-764 (2013).
20) S. W. Lee, C. H. Lee, J. A. Lee, S. S. Lee, “Vertically aligned carbon nanopillars with size and spacing control for a transparent field emission display,”
Nanotechnology, 24, 025301 (2013).
19) S. W. Lee, L. A. Berla, M. T. McDowell, W. D. Nix, Y. Cui, “Reaction Front Evolution during Electrochemical Lithiation of Crystalline Silicon Nanopillars,”
Israel Journal of Chemistry, 52, 1118-1123 (2012).
18) M. T. McDowell, I. Ryu, S. W. Lee, C. Wang, W. D. Nix, Y. Cui, “Studying the Kinetics of Crystalline Silicon Nanoparticle Lithiation with In Situ Transmission Electron Microscopy,”
Advanced Materials, 24, 6034-3041 (2012).
17) M. T. McDowell, S. W. Lee, C. Wang, Y. Cui, “The Effect of Metallic Coatings and Crystallinity on the Volume Expansion of Silicon during Electrochemical Lithiation/Delithiation,”
Nano Energy, 1, 401-410 (2012).
16) H. Wu*, G. Chan*, J. W. Choi, I. Ryu, Y. Yao, M. T. McDowell, S. W. Lee, A. Jackson, Y. Yang, L. Hu, and Y. Cui, “Stable Cycling of Double-Walled Silicon Nanotube Battery Anodes through Solid-Electrolyte Interphase Control,”
Nature Nanotechnology, 7, 310-315 (2012).
15) S. W. Lee, M. T. McDowell, L. A. Berla, W. D. Nix, and Y. Cui, “Fracture of crystalline silicon nanopillars during electrochemical lithium insertion,”
Proceedings of the National Academy of Sciences U.S.A., 109, 4080-4085 (2012).
[Highlighted at ‘In This Issue” of PNAS]
14) Y. Yang, S. Jeong, L. Hu, H. Wu, S. W. Lee, and Y. Cui, “Transparent lithium-ion batteries,”
Proceedings of the National Academy of Sciences U.S.A., 108, 13013-13018 (2011).
13) M. T. McDowell*, S. W. Lee*, I. Ryu, H. Wu, W. D. Nix, J. W. Choi, and Y. Cui, “Novel size and surface oxide effects in silicon nanowires as lithium battery anodes,”
Nano Letters, 11, 4018-4025 (2011).
12) S. W. Lee*, M. T. McDowell*, J. W. Choi, and Y. Cui, “Anomalous shape changes of silicon nanopillars by electrochemical lithiation,”
Nano Letters, 11, 3034-3039 (2011).
[Highlighted at MRS Bulletin 36, 576-578 (2011)]
11) C. H. Lee, S. W. Lee and S. S. Lee, “Field Emission of ITO-Coated Vertically Aligned Nanowire Array,”
Nanoscale Research Letters, 5, 1128-1131 (2010).
10) S. W. Lee, S. S. Lee, and E. H. Yang, “A Study on Field Emission Characteristics of Planar Graphene Layers Obtained from a Highly Oriented Pyrolyzed Graphite Block,”
Nanoscale Research Letters, 4, 1218-1221 (2009).
9) H.-J. Kwon, S. W. Lee, and S. S. Lee, “Braille dot display module with a PDMS membrane driven by a thermopneumatic actuator,”
Sensors and Actuators A, 154, 238-246 (2009).
8) J. A Lee, S. W. Lee, K. –C. Lee, S. I. Park and S. S. Lee, “Fabrication and characterization of freestanding 3D carbon microstructures using multi-exposures and resist pyrolysis,”
Journal of Micromechanics and Microengineering, 18, 035012 (2008).
7) S. W. Lee and S. S. Lee, “Application of Huygens-Fresnel diffraction principle for high aspect ratio SU-8 micro/nanotip array,”
Optics Letters, 33, 40-42 (2008).
6) S. W. Lee and S. S. Lee, “Rotation effect in split and recombination micromixing,”
Sensors and Actuators B, 129, 364-371 (2008).
5) S. W. Lee and S. S. Lee, “Shrinkage ratio of PDMS and its alignment method for the wafer level process,”
Microsystems Technology, 14, 205-208 (2008).
4) S. W. Lee and S. S. Lee, “Focal tunable liquid lens integrated with an electromagnetic actuator,”
Applies Physics Letters, 90, 121129 (2007).
[Highlighted at April 9, 2007 issue of Virtual Journal of Nanoscale Science & Technology]
3) S. W. Lee, D. S. Kim, S. S. Lee, and T. H. Kwon, “Split and recombination micromixer fabricated in PDMS 3-dimensional structure,”
Journal of Micromechanics and Microengineering, 16, 1067-1072 (2006).
2) D. S. Choi, S. W. Lee, S. S. Lee, and Y. T. Im, “Micro-channel flow analysis by fringe element reconstruction method,”
Journal of Micromechanics and Microengineering, 16, 571-579 (2006).
1) D. S. Kim, S. W. Lee, T. H. Kwon, and S. S. Lee, “A Barrier Embedded Chaotic Micromixer,”
Journal of Micromechanics and Microengineering, 14, 798-805 (2004).
Written in Korean
2) 이정아 (J. A Lee), 이석우 (S. W. Lee), 이승섭 (S. S. Lee), 박세일 (S. I. Park), 이광철 (K. C. Lee), “고종횡비 탄소 마이크로니들 어레이의 제조 및 생체응용을 위한 소수성 표면의 제어 (Fabrication of Carbon Microneedle Arrays with High Aspect Ratios and The Control of Hydrophobicity of These Arrays for Bio-Applications),”
대한기계학회 논문집 A (KSME A), 34, 1721-1725 (2010).
1) 김동성 (D. S. Kim), 권태헌 (T. H. Kwon), 이석우 (S. W. Lee), 이승섭 (S. S. Lee), “배리어가 포함된 카오스 마이크로 믹서의 개발 (Development of a Barrier Embedded Chaotic Micromixer),”
대한기계학회 논문집 A (KSME A), 28, 63-69 (2004).