Ming‐Way Lee

1.6k total citations
61 papers, 1.4k citations indexed

About

Ming‐Way Lee is a scholar working on Materials Chemistry, Renewable Energy, Sustainability and the Environment and Electrical and Electronic Engineering. According to data from OpenAlex, Ming‐Way Lee has authored 61 papers receiving a total of 1.4k indexed citations (citations by other indexed papers that have themselves been cited), including 50 papers in Materials Chemistry, 36 papers in Renewable Energy, Sustainability and the Environment and 35 papers in Electrical and Electronic Engineering. Recurrent topics in Ming‐Way Lee's work include Quantum Dots Synthesis And Properties (40 papers), Advanced Photocatalysis Techniques (27 papers) and Chalcogenide Semiconductor Thin Films (26 papers). Ming‐Way Lee is often cited by papers focused on Quantum Dots Synthesis And Properties (40 papers), Advanced Photocatalysis Techniques (27 papers) and Chalcogenide Semiconductor Thin Films (26 papers). Ming‐Way Lee collaborates with scholars based in Taiwan, Indonesia and United States. Ming‐Way Lee's co-authors include Auttasit Tubtimtae, Gou‐Jen Wang, Jen‐Bin Shi, Belete Asefa Aragaw, David J. Singh, R. Glosser, Lijun Zhang, Xin He, Wei‐Chih Sun and Junjie Liu and has published in prestigious journals such as Journal of the American Chemical Society, Journal of Applied Physics and Journal of Power Sources.

In The Last Decade

Ming‐Way Lee

61 papers receiving 1.3k citations

Peers — A (Enhanced Table)

Peers by citation overlap · career bar shows stage (early→late) cites · hero ref

Name h Career Trend Papers Cites
Ming‐Way Lee Taiwan 21 1.2k 923 554 106 92 61 1.4k
Kurtis Leschkies United States 8 1.4k 1.2× 931 1.0× 472 0.9× 151 1.4× 54 0.6× 10 1.5k
Thomas J. Whittles United Kingdom 14 878 0.8× 824 0.9× 245 0.4× 111 1.0× 116 1.3× 20 1.1k
A.U. Ubale India 18 833 0.7× 746 0.8× 172 0.3× 184 1.7× 93 1.0× 63 1.1k
Samuel Guérin United Kingdom 14 545 0.5× 491 0.5× 417 0.8× 98 0.9× 36 0.4× 26 890
C. Gümüş Türkiye 17 966 0.8× 923 1.0× 124 0.2× 89 0.8× 113 1.2× 43 1.1k
Mihail Caraman Moldova 12 635 0.5× 514 0.6× 231 0.4× 150 1.4× 60 0.7× 37 823
B. Elidrissi France 11 807 0.7× 585 0.6× 162 0.3× 95 0.9× 79 0.9× 19 927
Jonathan R. Bakke United States 16 695 0.6× 606 0.7× 301 0.5× 83 0.8× 47 0.5× 22 921
Yung‐Tang Nien Taiwan 16 736 0.6× 576 0.6× 201 0.4× 76 0.7× 33 0.4× 28 956
Pabitra Choudhury United States 16 439 0.4× 440 0.5× 362 0.7× 50 0.5× 42 0.5× 35 775

Countries citing papers authored by Ming‐Way Lee

Since Specialization
Citations

This map shows the geographic impact of Ming‐Way Lee's research. It shows the number of citations coming from papers published by authors working in each country. You can also color the map by specialization and compare the number of citations received by Ming‐Way Lee with the expected number of citations based on a country's size and research output (numbers larger than one mean the country cites Ming‐Way Lee more than expected).

Fields of papers citing papers by Ming‐Way Lee

Since Specialization
Physical SciencesHealth SciencesLife SciencesSocial Sciences

This network shows the impact of papers produced by Ming‐Way Lee. Nodes represent research fields, and links connect fields that are likely to share authors. Colored nodes show fields that tend to cite the papers produced by Ming‐Way Lee. The network helps show where Ming‐Way Lee may publish in the future.

Co-authorship network of co-authors of Ming‐Way Lee

This figure shows the co-authorship network connecting the top 25 collaborators of Ming‐Way Lee. A scholar is included among the top collaborators of Ming‐Way Lee based on the total number of citations received by their joint publications. Widths of edges represent the number of papers authors have co-authored together. Node borders signify the number of papers an author published with Ming‐Way Lee. Ming‐Way Lee is excluded from the visualization to improve readability, since they are connected to all nodes in the network.

All Works

20 of 20 papers shown
1.
2.
Wang, Yurou, et al.. (2024). Enhanced Photovoltaic Performance of Heavy-Metal-Free AgInS2 Quantum Dot-Sensitized Solar Cells Using a Facile SILAR Method. Journal of Electronic Materials. 53(12). 7239–7249. 3 indexed citations
3.
Kumar, Utkarsh, et al.. (2023). Highly sensitive CO gas sensor based on ternary metal sulfides PbSbS quantum dots: Experimental and DFT study. Journal of Alloys and Compounds. 967. 171688–171688. 9 indexed citations
4.
Wang, Yurou, et al.. (2023). Ternary alloyed Ba Cd1S nanocrystals: Synthesis, bandgap tuning, and photovoltaic performance. Optical Materials. 145. 114416–114416. 5 indexed citations
5.
Lien, Shang‐Wei, et al.. (2022). Band gap tunable quaternary PbxCd1−xS1−ySey quantum dot-sensitized solar cells with an efficiency of 9.24% under 1% sun. Sustainable Energy & Fuels. 6(11). 2783–2796. 5 indexed citations
6.
Lien, Shang‐Wei, et al.. (2020). Band gap engineered ternary semiconductor PbxCd1−xS: Nanoparticle‐sensitized solar cells with an efficiency of 8.5% under 1% sun—A combined theoretical and experimental study. Progress in Photovoltaics Research and Applications. 28(4). 328–341. 15 indexed citations
7.
Sebayang, Kerista, et al.. (2019). THE COMPARISON OF OPAQUE TiO2 AND TRANSPARENT TiO2 ON THE PERFORMANCE OF AgSbS2–SENSITIZED SOLAR CELL PREPARED BY SOLUTION PROCESSING. RASAYAN Journal of Chemistry. 14(1). 88–93. 4 indexed citations
8.
Singh, David J., et al.. (2019). Bandgap Tunable Ternary CdxSb2–yS3−δ Nanocrystals for Solar Cell Applications. ACS Omega. 5(1). 113–121. 6 indexed citations
9.
Chen, Liping, et al.. (2019). Tunable Optical Properties in SnxSb2–yS3: A New Solar Absorber Material with an Efficiency of near 5%. The Journal of Physical Chemistry C. 123(9). 5209–5215. 12 indexed citations
10.
Shi, Jen‐Bin, Cheng‐Ming Peng, Fu‐Chou Cheng, et al.. (2018). Manipulating the Temperature of Sulfurization to Synthesize α-NiS Nanosphere Film for Long-Term Preservation of Non-enzymatic Glucose Sensors. Nanoscale Research Letters. 13(1). 109–109. 5 indexed citations
11.
He, Xin, et al.. (2018). Dielectric Behavior as a Screen in Rational Searches for Electronic Materials: Metal Pnictide Sulfosalts. Journal of the American Chemical Society. 140(51). 18058–18065. 72 indexed citations
12.
Aragaw, Belete Asefa, Jifeng Sun, David J. Singh, & Ming‐Way Lee. (2017). Ion exchange-prepared NaSbSe2 nanocrystals: electronic structure and photovoltaic properties of a new solar absorber material. RSC Advances. 7(72). 45470–45477. 14 indexed citations
13.
Aragaw, Belete Asefa, et al.. (2016). Lead tin sulfide (Pb1−Sn S) nanocrystals: A potential solar absorber material. Journal of Colloid and Interface Science. 488. 246–250. 9 indexed citations
14.
Aragaw, Belete Asefa, et al.. (2016). Lead antimony sulfide (Pb5Sb8S17) solid-state quantum dot-sensitized solar cells with an efficiency of over 4%. Journal of Power Sources. 312. 86–92. 21 indexed citations
15.
Chen, Yuwei, et al.. (2016). Pb5Sb8S17Liquid-Junction Quantum Dot-Sensitized Solar Cells: Improved Performance by Modifying the Particle Size of the TiO2Electrode. Journal of The Electrochemical Society. 163(14). H1122–H1126. 6 indexed citations
16.
Aragaw, Belete Asefa, et al.. (2016). Ternary CuBiS2 nanoparticles as a sensitizer for quantum dot solar cells. Journal of Colloid and Interface Science. 473. 60–65. 47 indexed citations
17.
Lee, Ming‐Way, et al.. (2011). Cu2-xS quantum dot-sensitized solar cells. Electrochemistry Communications. 13(12). 1376–1378. 49 indexed citations
18.
Tubtimtae, Auttasit, et al.. (2010). ZnO-Nanorod Dye-Sensitized Solar Cells: New Structure without a Transparent Conducting Oxide Layer. International Journal of Photoenergy. 2010. 1–5. 26 indexed citations
19.
Lee, Ming‐Way, et al.. (2009). Angle-Resolved Field Emission of Individual Carbon Nanotubes. Japanese Journal of Applied Physics. 48(7R). 72402–72402. 1 indexed citations
20.
Wang, Gou‐Jen, Ming‐Way Lee, & Yihong Chen. (2008). A TiO2/CNT Coaxial Structure and Standing CNT Array Laminated Photocatalyst to Enhance the Photolysis Efficiency of TiO2. Photochemistry and Photobiology. 84(6). 1493–1499. 17 indexed citations

Rankless uses publication and citation data sourced from OpenAlex, an open and comprehensive bibliographic database. While OpenAlex provides broad and valuable coverage of the global research landscape, it—like all bibliographic datasets—has inherent limitations. These include incomplete records, variations in author disambiguation, differences in journal indexing, and delays in data updates. As a result, some metrics and network relationships displayed in Rankless may not fully capture the entirety of a scholar's output or impact.

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