Something is happening inside the cell that classical biochemistry was never designed to explain.
Over the past two decades, a quiet revolution has been building at the intersection of quantum physics and biology. Experiments across diverse systems — from bird navigation to stem cell differentiation to microtubule assembly — have revealed that weak magnetic fields and isotope substitutions can alter biological outcomes in ways that defy classical thermodynamic explanations. The energies involved
are a million times smaller than the thermal noise at body temperature. And yet the effects are real, reproducible, and statistically overwhelming.
The mechanism behind these observations is quantum spin chemistry — specifically, the radical pair mechanism, in which transient pairs of molecules with unpaired electrons oscillate between quantum spin states whose interconversion is sensitive to external magnetic fields and nearby nuclear spins through a quantum interaction known as hyperfine coupling.
In this live presentation, ISF researcher William Brown surveys the latest breakthroughs in quantum biochemistry and explores what they reveal about the deep architecture of living systems:
Whether you are a physicist curious about biology, a biologist curious about quantum mechanics, or simply someone who wants to understand the cutting edge of what we know about how life works at its most fundamental level, this presentation offers a rigorous, accessible, and deeply fascinating window into one of the most exciting frontiers in modern science.
No prior background in quantum physics is required.