Quantum physics and biology: the local wavefunction approach

TL;DR

This paper proposes that in the universe, only local wave functions exist, explaining the emergence of classical and biological complexity without requiring a universal wave function, and aligns with quantum chemistry in biological systems.

Contribution

It introduces a local wavefunction framework for quantum physics and biology, challenging the notion of a universal wave function and explaining macro-level emergence.

Findings

Local wave functions are sufficient for biological and macroscopic systems.

Contextual wave function collapse supports a version of the Copenhagen interpretation.

Quantum chemistry approaches align with the local wavefunction perspective.

Abstract

Is there a single linearly evolving Wave Function of the Universe that is able to lead to all the nonlinearities we see around us? This proposal seems a priori highly implausible. I claim that instead, in the real Universe, generically only local wave functions exist. Non-local wave functions occur for carefully engineered contexts such as Bell experiments, but there is no single wave function for a cat or similar macroscopic objects such as a brain. Contextual wave function collapse leads to a defensible version of the Copenhagen interpretation, where classical macro levels provide the context for quantum events and biological emergence. Complexity arises via adaptive multiscale modular hierarchical structures that enable logical branching to emerge from the underlying linear physics. Each emergent level is causally effective because of the confluence of upwards and downwards causation that takes place consistently with the underlying physics. Quantum chemistry approaches in biological contexts fit this local wavefunction picture.