Building a quantum superposition of conscious states with integrated information theory
Kelvin J. McQueen, Ian T. Durham, Markus P. Mueller
arXiv Preprint Archive September 25, 2023
Summary
Could consciousness itself be in a quantum superposition? A compelling analysis, using integrated information theory, proposes a quant-ph circuit design for a simple system to achieve a superposition of conscious states. This suggests that if the theory holds, even basic systems can be conscious and exist in multiple states simultaneously. This work offers new insights into models where such superpositions might collapse.
Abstract
Could there be a quantum superposition of consciousness, as in the Wigner's friend thought experiment? The integrated information theory (IIT) of consciousness has turned this into a well-defined question. According to IIT, consciousness is a measurable physical quantity given by integrated information ($\Phi$), such that the amount of consciousness in a system corresponds to its amount of $\Phi$. We use the most recent IIT formalism (IIT4.0) to analyze the simplest non-zero $\Phi$ system known as a feedback dyad. We then propose a circuit that puts the dyad into a superposition of states which, according to IIT, would correspond to a superposition of conscious states. We refer to this as "Schr\"odinger's dyad". We therefore show that either IIT is false or the simple dyad is conscious and can easily be put into a superposition of conscious states. We then identify the simplest possible consciousness-collapse model, which predicts that this superposition is unstable and collapses at a rate determined by a measure of difference between the superposed conscious states. Our analysis will enable us to make a number of key observations about the general structure of integrated information theory (IIT2.0, IIT3.0, IIT4.0, and QIIT) and the general structure of consciousness-collapse models.