A Groundbreaking research paper by a team of international and Indian physicists, including Vishwanath Barve, Samarth Naik, and Avni Mishra, challenges one of the oldest foundations in classical mechanics—Newton’s First Law of Motion. The study, featured in the International Journal of Research Publication and Reviews, rigorously explores how Newton’s law breaks down under high-energy and relativistic conditions, demanding a new, more accurate definition of motion.
The authors present strong theoretical, mathematical, and experimental evidence—ranging from muon decay to spacetime curvature—that inertial motion is not absolute, but relative, quantum-influenced, and shaped by vacuum fluctuations. This reassessment brings classical mechanics in alignment with both Einstein’s Relativity and Quantum Field Theory, pushing forward our understanding of motion at the deepest levels.
The contribution of Indian researchers to this work has been particularly notable, marking yet another milestone where young minds from India lead the dialogue in reshaping global physics. The paper could pave the way for improved models in quantum technologies, interstellar dynamics, and theoretical cosmology.
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