Dr. Varedi-Koulaei is also an active member of several professional associations in the field of mechanical engineering, through which he continues to contribute to global research discussions. He regularly shares his work on platforms like Google Scholar and ResearchGate, connecting with a broader academic and professional audience.

Dr. Varedi-Koulaei’s research focuses on several key areas, including parallel robots, mechanism design and synthesis, and the application of machine learning and neural networks to optimize mechanical systems. His work in these areas has resulted in numerous publications and ongoing projects, contributing to advancements in both academia and industry.

Manpreet Kaur’s research interests revolve around advancing energy conversion and storage technologies through innovative material science. Her work focuses on electrochemistry and nanomaterial synthesis, particularly in developing and optimizing metal-semiconductor nanostructures for energy applications. She investigates core-shell nanomaterials and hybrid nanostructures for use in polymer electrolyte fuel cells, electrolysers, and batteries, aiming to enhance their performance and efficiency. Additionally, her research explores electro- and photocatalytic processes to convert methane and nitrogen into valuable chemicals and fuels. She is also involved in the synthesis of advanced materials such as graphene and MXenes for various applications, including ammonia and methanol production. Kaur’s expertise extends to plasmonic catalysis and the use of quantum dots in selective catalytic oxidation, contributing to more sustainable and efficient energy systems. Her work integrates theoretical and practical approaches to address global energy challenges.

Manpreet Kaur, PhD, exhibits a robust set of research skills crucial for advancing the field of materials science and energy conversion. Her expertise in electrochemistry and nano-materials synthesis is demonstrated through her work with core-shell nanomaterials and hybrid nanostructures, essential for applications in fuel cells, electrolysers, and sensors. Proficient in electrochemical measurements using techniques such as Rotating Disk Electrode (RDE) and gas chromatography–mass spectrometry (GC–MS), she excels in analyzing volatile components and optimizing catalytic reactions. Her skills extend to cleanroom techniques including reactive ion etching and chemical vapor deposition, supporting her research on plasmonic materials and photovoltaics. Additionally, Manpreet is adept in software tools like RSOFT and COMSOL for electromagnetic and energy transfer simulations. Her extensive training in synthesis methods, including wet-chemical and solvothermal techniques, underscores her versatility in developing advanced materials for energy and environmental applications.