Post-Doc, University of Seoul, South Korea.
Minwoo Park is a Post-Doctoral Researcher at the University of Seoul, specializing in computational materials science and condensed matter physics. He received his Ph.D. in Physics from Konkuk University, where he studied the Raman effects of few-layer two-dimensional materials using first-principles calculations. His research focuses on energy materials, superconductivity, and quantum materials. He has contributed significantly to the study of 2D materials, quantum spin Hall properties, and lithium-ion battery anode materials. His work has been published in leading journals, such as npj Computational Materials and JACS, with over 950 citations. Minwoo holds a patent for high-capacity anode materials for batteries and has collaborated with experimental teams on various projects, including graphene analysis and superconductivity. He is a member of the Korean Physical Society.
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Education :
Minwoo Park completed his undergraduate and graduate studies in Physics, earning a Ph.D. from Konkuk University, South Korea. His doctoral research focused on the Raman effects of few-layer two-dimensional (2D) materials, where he utilized first-principles calculations to explore their unique properties. This research set the foundation for his career in computational materials science. Currently, as a Post-Doctoral Researcher at the University of Seoul, Minwoo investigates superconductivity in doped SrTiO3 and continues to contribute to the understanding of energy materials and quantum materials. Throughout his education, Minwoo engaged in advanced studies in condensed matter physics, materials science, and quantum physics, combining theoretical models with computational simulations. His rigorous academic training and innovative approach have positioned him as a leader in his field. Additionally, his ongoing post-doctoral work allows him to collaborate with both experimental and theoretical research teams globally, advancing the boundaries of materials science.
Experience :
Minwoo Park’s professional experience spans both academic research and scientific collaborations. After completing his Ph.D., he joined the University of Seoul as a Post-Doctoral Researcher, focusing on the superconductivity of doped SrTiO3. His work integrates computational materials science, condensed matter physics, and quantum physics, producing high-impact research in energy materials and quantum materials. Minwoo’s most notable achievements include publishing in prestigious journals such as npj Computational Materials, JACS, and Advanced Functional Materials, contributing significantly to battery technology and quantum spin Hall systems. His experience also includes working on molecular dynamics simulations, where he analyzed the effects of mechanical stress on graphene ripples. He has provided critical theoretical insights to experimental teams, helping shape the direction of 2D material research. Minwoo holds one patent related to lithium-ion battery anode materials, showcasing his ability to translate scientific innovation into real-world applications. He is actively involved in collaborations, further expanding his research impact.
Research Focus :
Minwoo Park’s research focuses on computational materials science, with an emphasis on condensed matter physics and two-dimensional (2D) materials. His work explores the electronic and structural properties of 2D materials, such as graphene, graphdiyne, and transition metal dichalcogenides. He has made significant contributions to the study of novel anode materials for lithium-ion batteries and the design of quantum materials with spintronic properties, such as quantum spin Hall insulators. Minwoo’s research has advanced the understanding of electron-phonon coupling in superconducting materials, particularly doped SrTiO3. By using first-principles calculations and molecular dynamics simulations, he investigates how different material properties can be tailored for energy storage, quantum devices, and nanotechnology applications. His contributions to the field of computational materials science aim to bridge the gap between theory and practical applications, making his research crucial for the development of future energy technologies and advanced quantum materials.
Publications Titles :
- Multilayer graphynes for lithium ion battery anode ⚡🔋
- 2D transition metal dichalcogenide heterostructures for p‐and n‐type photovoltaic self‐powered gas sensor ☀️🔬
- Graphdiyne as a high-capacity lithium ion battery anode material ⚡🔋
- Molecular-level understanding of continuous growth from iron-oxo clusters to iron oxide nanoparticles 🧪🔬
- Widely tunable band gaps of graphdiyne: an ab initio study 🧑🔬📊
- Raman spectra shift of few-layer IV-VI 2D materials 📈🎶
- Exotic geometrical and electronic properties in hydrogenated graphyne 💡⚛️
- High-throughput screening of metal-porphyrin-like graphenes for selective capture of carbon dioxide 🌍🔬
- Doping effect in graphene-graphene oxide interlayer ⚙️💨
- Design of 2D massless Dirac fermion systems and quantum spin Hall insulators based on sp–sp2 carbon sheets 🧑🔬✨
- Configuration of ripple domains and their topological defects formed under local mechanical stress on hexagonal monolayer graphene 🌀🌍
- Fe–Porphyrin-like nanostructures for selective ammonia capture under humid conditions 💨⚗️
- Gated MoSi2N4 monolayer as a highly efficient nanosensor towards selected common pollutants 🌿🧪
- sp–sp2 Carbon Sheets as Promising Anode Materials for Na-Ion Batteries ⚡🔋
- Carbyne bundles for a lithium-ion-battery anode ⚡🔋
- Improved Transport of Adenosine Incorporated in Lipid Nanoparticles across Reconstructed Human Epidermis 💉👨🔬
- Efficient detection of specific volatile organic compounds associated with COVID-19 using CrX2 (X= Se, Te) monolayers 🦠💨
- Wedge energy bands of monolayer black phosphorus: a first-principles study 🧑🔬⚛️
- Corrigendum: High-throughput screening of metal-porphyrin-like graphenes for selective capture of carbon dioxide 🌍🔬
- Vertical Dielectric of Conducting Functionalized Few-Layer MoS2 🔬💡