Ming-Fa Lin

Ming-Fa Lin (Taiwanese Mandarin: 林 明發, Taiwanese Hokkien: Lîm Bîng-Huat; July 2, 1962 - August 14, 2023 ) was a Taiwanese theoretical physicist. He was a distinguished professor in the Department of Physics in the National Cheng Kung University, Tainan, Taiwan. His main scientific interests focus on the essential properties of carbon-related materials and low-dimensional systems. He presided over more than 10 Ministry of Science and Technology research projects. He published more than 300 peer-reviewed articles and over 10 academic books. His research principles include innovation, uniqueness, diversity, completeness, and generalization. In 2023, Prof. Ming-Fa Lin was awarded the top 2% of the world's top scientists for honoring his career-long research works.

He received a B.S. degree in physics from National Cheng Kung University in 1984. Later he received the M.S., and Ph.D. degrees in physics from National Tsing Hua University (Hsinchu, Taiwan) in 1986 and 1993, respectively.

As a postdoctoral fellow in physics from the National Tsing-Hua University, he stayed until 1995. After three years in the National Chiao Tung University (Hsinchu, Taiwan), 1995–1997, he became a professor in the National Cheng Kung University. M. F. Lin was a member of the American Physical Society, American Chemical Society, Physical Society of Taiwan, and Taiwan Association of University Professors.

Education

 * 1980.08 - 1984.07: B.S., Department of Physics, National Cheng Kung University
 * 1984.08 - 1986.07: M.A., Department of Physics, National Tsing Hua University
 * 1988.08 - 1993.07: Ph. D., Department of Physics, National Tsing Hua University

Professional experience

 * 1986.08 - 1987.07: Lecturer of Physics Teaching and Research Center, Feng Chia University
 * 1993.08 - 1995.07: Postdoctoral fellow of Physics, National Tsing Hua University
 * 1995.08 - 1997.07:	Postdoctoral fellow of Electrophysics, National Chiao Tung University
 * 1997.08 - 1998.07: Assistant Professor of Physics, National Cheng Kung University
 * 1998.08 - 2001.07: Associate Professor of Physics, National Cheng Kung University
 * 2001.08 - 2006.07: Professor of Physics, National Cheng Kung University
 * 2006.08 - 2023.08: Distinguished Professor of Physics, National Cheng Kung University

Research fields
Professor Lin has performed research in the fields of solid-state physics, condensed matter physics, materials science, nano science, carbon nanotube, graphene, graphene nanoribbon, carbon-related materials, low-dimensional materials, semiconductor, and energy materials.

Honors and awards

 * 1997.08 - 1998.07: Research Award, National Science Council, Taiwan
 * 1998.08 - 1999.07: Research Award, National Science Council, Taiwan
 * 1999.08 - 2000.07: Research Award, National Science Council, Taiwan
 * 2000.08 - 2001.07: Research Award, National Science Council, Taiwan
 * 2023.10: Career-long top 2% of the world's top scientists in 2022, Elsevier Data Repository

Optical properties of graphene nanoribbons
In 2000, Lin cooperated with Shyu to calculate the optical properties of graphene nanoribbons numerically. The different selection rules for optical transitions in zigzag and armchair graphene nanoribbons were first reported. In 2007, these results were supplemented by a comparative study of zigzag graphene nanoribbons with single-wall armchair carbon nanotubes by Hsu and Reichl. In 2011, Lin conducted Chung et al. to analyze and report the edge-dependent optical selection rules analytically. In the meantime, Sasaki et al. also reported their theoretical prediction as a confirmation.

The selection rule in zigzag graphene nanoribbons differs from that in armchair graphene nanoribbons. Optical transitions between the edge and bulk states enrich the low-energy region absorption spectrum ($$<$$ 3 eV) with high-intensity absorption peaks. Analytical derivation of the numerically obtained selection rules was presented in 2011. The selection rule for the incident light polarized longitudinally to the zigzag nanoribbon axis is that $$|\Delta J | = |J^c - J^v| = odd$$, where $$ J^c$$ and $$J^v$$ are index number for the conduction and valence energy subbands, respectively. For armchair graphene nanoribbons, the selection rule is $$\Delta J = J^c - J^v = 0$$.

PI

 * 1) 1997.11 - 1998.07: Physical Properties of Carbon Nanotubes (I)
 * 2) 1998.08 - 1999.07: Physical Properties of Carbon Toroids (I)
 * 3) 1999.08 - 2000.07: Physical Properties of Carbon Toroids and Carbon Nanotubes (III)
 * 4) 2000.08 - 2001.07: Physical Properties of Graphite-Related Systems and Two-Dimensional Modulated Electronic Systems (I)
 * 5) 2001.08 - 2002.07: Physical Properties of Graphite-Related Systems and Two-Dimensional Modulated Electronic Systems (II)
 * 6) 2002.08 - 2003.07: Physical Properties of Graphite-Related Systems and Two-Dimensional Modulated Electronic Systems (III)
 * 7) 2003.08 - 2004.07: Many-Body Physical Properties of Carbon Nanotubes (I)
 * 8) 2004.08 - 2005.07: Many-Body Physical Properties of Carbon Nanotubes (II)
 * 9) 2005.08 - 2006.07: Many-Body Physical Properties of Carbon Nanotubes (III)
 * 10) 2006.08 - 2007.07: Physical Properties of Low-Dimensional Carbon-Related Systems (I)
 * 11) 2008.08 - 2009.07: Physical Properties of Low-Dimensional Carbon-Related Systems (II)
 * 12) 2007.08 - 2008.07: Physical Properties of Low-Dimensional Carbon-Related Systems (III)
 * 13) 2009.08 - 2010.07: Electronic Properties of Layered Systems in the Presence of External Fields (I)
 * 14) 2010.08 - 2011.07: Electronic Properties of Layered Systems in the Presence of External Fields (II)
 * 15) 2011.08 - 2012.07: Electronic Properties of Layered Systems in the Presence of External Fields (III)
 * 16) 2012.08 - 2013.07: Electronic Properties of Layered Systems in the Presence of External Fields (IV)
 * 17) 2013.08 - 2014.07: Physical Properties of Graphene Systems (I)
 * 18) 2014.08 - 2015.07: Physical Properties of Graphene Systems (II)
 * 19) 2015.08 - 2016.07: Physical Properties of Graphene Systems (III)
 * 20) 2016.08 - 2017.07: Essential Properties of IV-Group 2D Systems (I)
 * 21) 2017.08 - 2018.07: Essential Properties of IV-Group 2D Systems (II)
 * 22) 2018.08 - 2019.07: Essential Properties of IV-Group 2D Systems (III)
 * 23) 2019.08 - 2020.07: Theoretical Frameworks for Essential Properties of Layered Systems (I)
 * 24) 2020.08 - 2021.07: Theoretical Frameworks for Essential Properties of Layered Systems (II)
 * 25) 2021.08 - 2022.07: Theoretical Frameworks for Essential Properties of Layered Systems (III)
 * 26) 2022.08 - 2023.07: The Basic Science under the Quasi-Particle Framework (I)
 * 27) 2023.08 - 2024.07: The Basic Science under the Quasi-Particle Framework (II)

Co-PI

 * 1) 2014.08 - 2015.07: MBE Growth, Electronic, Spintronic and Optical Studies on Topological Insulator Films and Advanced Applications (I)
 * 2) 2015.08 - 2016.07: MBE Growth, Electronic, Spintronic and Optical Studies on Topological Insulator Films and Advanced Applications (II)
 * 3) 2016.08 - 2017.07: MBE Growth, Electronic, Spintronic and Optical Studies on Topological Insulator Films and Advanced Applications (III)

Selected publications
More than 300 peer-reviewed articles are published and listed in abstract and citation databases.

The selected publications are listed.

Books

 * 1) Optical Properties of Graphene in Magnetic and Electric Fields
 * 2) Theory of Magnetoelectric Properties of 2D Systems
 * 3) Structure- and Adatom-Enriched Essential Properties of Graphene Nanoribbons
 * 4) Handbook of Green Energy Materials
 * 5) Coulomb Excitations and Decays in Graphene-Related Systems
 * 6) Diverse Quantization Phenomena in Layered Materials
 * 7) Geometric and Electronic Properties of Graphene-Related Systems: Chemical Bonding Schemes
 * 8) Silicene-Based Layered Materials
 * 9) Electronic and Optical Properties of Graphite-Related Systems
 * 10) Lithium-Ion Batteries and Solar Cells: Physical, Chemical, and Materials Properties
 * 11) Rich Quasiparticle Properties of Low Dimensional Systems
 * 12) First-Principles Calculations for Cathode, Electrolyte and Anode Battery Materials
 * 13) Lithium-Related Batteries: Advances and Challenges
 * 14) Diverse Quasiparticle Properties of Emerging Materials: First-Principles Simulations
 * 15) Energy Storage and Conversion Materials: Properties, Methods, and Applications
 * 16) Fundamental Physicochemical Properties of Germanene-related Materials: A Theoretical Perspective
 * 17) Rich Quasiparticle Properties in Layered Graphene-Related Systems
 * 18) Chemical Modifications of Graphene-Like Materials

Review articles

 * 1) Magneto-electronic properties of multilayer graphenes
 * 2) Electronic and optical properties of graphene nanoribbons in external fields