Neuroscience traditionally studies brain activity at the molecular, cellular, and neural network levels, treating the brain as a solid medium where excitations propagate along long fibers. However, Kinematics of Brain Activities expands this view by considering energy exchanges across thousands of interacting networks, treating them as elastic and oscillatory systems. The oscillatory energy transfer occurs through stress-straining of neural tissues at the smallest scale, synchronizing the firing of neurons and forming a dynamic balance state. This paper introduces the principles of strain carrier waves, stress-straining flow, and the transformation of neural substrates into a continuum that supports cognition and memory. The study bridges neuroscience and psychology, offering a framework for understanding how localized neural strain flows integrate into larger cognitive processes and consciousness states.
This article is a base of the interview between the author and A.I.