Ariel University | Israel
Manish Yadav is a dedicated researcher in electrochemical CO₂ reduction, with expertise in advanced nanomaterials, catalysis, and sustainable energy solutions. He recently completed his PhD in Chemistry at Ariel University, Israel, where his doctoral work focused on understanding the nature of laser-processed, metal-doped carbon-based materials for CO₂ electro-reduction into valuable commodity products. His research involved the synthesis of highly graphitized reduced carbon nanodots through laser irradiation, controlled doping of copper nanomaterials in carbon supports, and the development of laser-assisted single-atom catalysts. Prior to this, he pursued his BS-MS Integrated degree at the Indian Institute of Science Education and Research (IISER) Mohali, where his thesis explored the kinetic stability of halogenated azobenzene isomers through structural, kinetic, and computational studies. His academic journey is marked by multiple recognitions, including the prestigious Excellence Award in Doctoral Research in 2023 and 2025. His findings have been presented in several international conferences across Israel, France, Spain, and Germany, and he has contributed high-impact publications in journals such as Carbon and ACS Applied Energy Materials. With strong skills in spectroscopy, microscopy, electrochemistry, and computational modeling, he continues to advance the design and mechanistic understanding of catalysts for clean energy and environmental sustainability.
Featured Publications
Porat, H., Lal, A., Dutta, A., Yadav, M.K., Sesu, D.C., Minnes, R., & Borenstein, A. (2025). Nickel-oxide embedded laser-induced graphene for high-performance supercapacitors. Nanoscale.
Yadav, M.K., Dutta, A., Lal, A., Porat, H., Zidki, T., & Borenstein, A. (2025, September 8). Laser-Induced Synthesis of Copper-Based Nanomaterials for CO₂ Electroreduction into Methanol. ACS Applied Energy Materials.
Lal, A., Porat, H., Dutta, A., Yadav, M.K., & Borenstein, A. (2025, June 25). Laser‐Induced HKUST‐1 Derived Porous Electrocatalyst: An Innovative Approach to Boost Sustainable Ammonia Synthesis. Advanced Sustainable Systems.
Dutta, A., Manjunath, K., Porat, H., Lal, A., Yadav, M.K., Mandić, V., Laikhtman, A., Zak, A., Makrinich, G., & Borenstein, A. et al. (2024). Plasma-Treated 1D Transition Metal Dichalcogenides for Efficient Electrocatalytic Hydrogen Evolution Reaction. Journal of Materials Chemistry A.
Yadav, M.K., & Borenstein, A. (2022, October). Is precarbonization necessary for effective laser graphitization? Carbon.
Das, D., Yadav, M.K., Singla, L., Kumar, A., Karanam, M., Dev, S., & Choudhury, A.R. (2020, November 30). Understanding of the kinetic stability of cis-isomer of azobenzenes through kinetic and computational studies. ChemistrySelect.