Fascinated by the mechanisms governing high-altitude hazards in Earth's most vulnerable mountain regions, I pursue research that bridges technological innovation with cryosphere science. My interdisciplinary journey began with a Bachelor of Science in Electronics and Communication, which equipped me with expertise in instrumentation and signal processing skills that later proved instrumental in developing field-based monitoring solutions. Recognizing the transformative potential of geospatial technologies, I further earned a Master’s of Science in Geoinformatics, where I discovered how remote sensing could address critical environmental challenges in spatially heterogeneous, data-scarce regions like the Himalaya.

I am currently a PhD candidate investigating glacial lake outburst flood hazards through an integrated framework that combines remote sensing, artificial intelligence, and field-based geophysical surveys. My research aims to unravel the complex glacier-lake-moraine interactions that govern differential GLOF risk in the Himalaya and to advance predictive modelling capabilities through artificial intelligence for mountain communities facing escalating climate-driven risks. This work addresses a fundamental gap in cryo-hazard science that can function effectively in regions where conventional monitoring infrastructure is absent or inadequate.

Beyond advancing scientific understanding of glacial hazards, I am committed to translating research insights into practical solutions. Leveraging my multidisciplinary background, I am focused on developing simplified, cost-effective sensor-based instrumentation for continuous high-altitude monitoring. With these technological interventions, my long-term goal is to enhance real-time data acquisition and strengthen early warning capabilities for vulnerable mountain communities to contribute towards achieving sustainable mountain resilience in the fragile Himalaya.