I use fluid flow, chemistry, and machine learning to discover new materials quickly at Process Modelling, Automation and Robotisation (PROMAR) Group, Materials Research and Technology (MRT) Department, Luxembourg Institute of Science and Technology, Luxembourg-4422.
I am dedicated to advancing materials science as a Research and Technology Scientist (PI) specializing in microfluidics, droplets, and accelerated materials discovery (AMD). My work focuses on clean energy, flow synthesis, machine learning, sustainability, and thermal management. I'm passionate about innovation and its societal impact. My research spans lab-on-a-chip tech, PGM-less catalysts, composites, automation, metal alloys, energy harvesting, and green cooling. My expertise in fluid physics, microfluidics, and materials science has driven progress in flow chemistry-based AMD, droplet microfluidics, lab-on-a-chip tech, green cooling, and multiphysics simulations. I'm committed to pushing the boundaries of my research field to bring Luxembourg to the forefront of AMD research.
Current Role and Interests
1) Accelerated Materials Discovery
Develop a combinatorial setup for multi-metal particles synthesis
Establish closed-loop programmable control of the synthesis unit
Integrate machine learning for accelerated materials discovery
Obtain superior materials in-line with the futuristic plan of the Materials Research & Technology department at the Luxembourg Institute of Science and Technology (LIST), Luxembourg.
2) Vision for the Advancement in Science & Technology
Establish a state-of-the-art AI-integrated accelerated materials discovery unit in the PROMAR group (Process Modelling, Automation, and Robotisation) at LIST, Luxembourg, to achieve a paradigm shift in materials research and technologies.
Develop highly skilled futuristic materials scientists for Luxembourg, contributing to rapid materials science and engineering development.
Recent Publications
A magnetic nanofluid device for excellent passive cooling of light emitting diodes
Magnetically Responsive Peptide Coacervates for Dual Hyperthermia and Chemotherapy Treatments of Liver Cancer
Hybrid thermomagnetic oscillator for cooling and direct waste heat conversion to electricity
Research Highlights
Project Lead for CREATE Phase II project under "Nanomaterials for Energy & Water Management" program in collaboration with The Hebrew University of Jerusalem.
Development of application specific new designs, prototypes, and devices for magnetofluidic & thermomagnetic cooling & energy harvesting systems.
Development of numerical simulation models for enhanced device performance.
Established experimental methods for quantitative flow behavior and PIV analysis.
Prolific mentor: trained & guided 3 Ph.D.'s, 1 Project Officer, &1 Research Fellow.
Developed micro-magnetofluidic (MMF) setup for high throughput Janus particle synthesis.
Established numerical simulations & experimental techniques for droplet control, merging, mixing, and magnetic separation.
Setup also useful for multi-functional Janus fibers & polymeric particles.
3) Journal Publications and Referee
2 Keynote Talks, 24 Conference Presentations, & 28+ Publications (15+ in high impact journals).
Reviewer for Prestigious Journals: Nature, RSC, AIP, MDPI Publ. Group
Magnetic Cooling,
Thermo-Magnetofluidics
Thermo-Magnetofluidics
Lab-on-a-Chip Droplet Merging, Mixing
“We cannot solve our problems with the same thinking we used when we created them.” -Albert Einstein