Dr. Subhash Singh | Material Science | Best Researcher Award

Dr. Subhash Singh | Senior Scientist / Research Faculty | University of Rochester | United States

Academic Background

He completed his foundational studies in physics with a focus on laser spectroscopy, optical metrology, and the spectroscopic diagnosis of laser-produced metal plasmas. His academic journey spans undergraduate, postgraduate, and doctoral education at a leading Indian university known for its contributions to physical sciences. His citation record reflects substantial influence across disciplines. On Google Scholar, his work has been cited more than seven thousand times with an h-index exceeding forty. On Scopus, his research output includes over one 126 indexed documents with citations recorded across more than 4626 works and an h-index above 36. These indicators highlight sustained research impact and continued relevance in multiple scientific domains.

Research Focus

His research centers on ultrafast laser–matter interactions, plasma science, nanomaterials, and surface engineering for energy and environmental applications. He also explores thermal management, renewable desalination, direct air capture, and photonic sensing using advanced plasmonic and nanoscale platforms.

Work Experience

He has served in senior research and academic roles across prominent institutions in the United States, China, Ireland, and India. His work includes leading femtosecond laser laboratories, supervising research teams, managing laboratory operations, mentoring postgraduate and undergraduate researchers, and writing successful grants valued in the millions. He has also developed experimental facilities, established new research laboratories, and contributed to interdisciplinary collaborations in optics, materials science, and sustainable technologies. His responsibilities have ranged from designing experimental systems and developing energy solutions to directing doctoral research groups and leading institutional scientific initiatives.

Key Contributions

He has advanced knowledge in femtosecond laser surface processing, evaporation-driven desalination, direct cooling technologies, and nanoparticle synthesis in liquids. His investigations into higher harmonic generation, plasmonic sensing, metasurfaces, and photovoltaic-thermal integration have influenced both applied and fundamental research. He has also contributed to laser doping of semiconductors, solar cell fabrication, and nanostructured catalyst development.

Awards and Recognition

His research achievements have resulted in high-impact publications, international collaborations, funded projects, and recognition through editorial and invited research roles.

Professional Roles and Memberships

He has served as a guest editor for scientific journals, supervised doctoral and master’s candidates, and contributed to institutional committees. His leadership includes directing research groups, conducting weekly progress reviews, hiring academic staff, and coordinating laboratory operations in optics, plasmonics, and materials science. He is affiliated with professional communities through publications, collaborations, peer-review, and editorial contributions.

Publication Profile

Scopus

ORCID

Featured Publications

Singh, S. C., Vorbeyev, A., Madsen, M., Wei, R., & Guo, C. (2025). Maintenance-free evaporative cooling using laser-processed superwicking surfaces. Cell Reports Physical Sciences.

Singh, S. C., Tang, L., Wei, R., & Guo, C. (2025). Solar-thermal purification with high interfacial efficiency. Advanced Functional Materials.

Xu, T., Wei, R., Singh, S. C., & Guo, C. (2025). Solar thermoelectric performance enhancement through spectral engineering. Light: Science & Applications.

Konda, S. R., Barik, P., Singh, S. C., & Rao, V. (2025). Nonlinear optical modulation in MoS2 media. Advanced Optical Materials.

Saraj, C. S., Singh, S. C., Verma, G., Li, W., & Guo, C. (2023). Pulsed-laser ablated nanocomposites for hydrogen generation. Applied Surface Science Advances.

Impact Statement / Vision

His work bridges laser physics, nanotechnology, and sustainable engineering to address global energy, water, and environmental challenges. He envisions advancing laser-assisted material processing and photonic technologies to deliver scalable solutions for clean energy, climate resilience, and resource optimization.