A Planck Radiation and Quantization Scheme for Human Cognition and Language

TL;DR

This paper introduces a radiation quantization model for human cognition and language, explaining how 'meaning dynamics' cause words to cluster, and explores implications for memory and thought through quantum statistical frameworks.

Contribution

It extends quantum cognition by applying a radiation quantization scheme, linking Bose-Einstein statistics and 'meaning dynamics' to language and memory modeling.

Findings

Words tend to cluster due to 'meaning dynamics' similar to photon behavior.

Entanglement is essential for maintaining 'meaning dynamics' in cognition.

Fermi-Dirac statistics explain how memory preserves word distinctiveness.

Abstract

As a result of the identification of 'identity' and 'indistinguishability' and strong experimental evidence for the presence of the associated Bose-Einstein statistics in human cognition and language, we argued in previous work for an extension of the research domain of quantum cognition. In addition to quantum complex vector spaces and quantum probability models, we showed that quantization itself, with words as quanta, is relevant and potentially important to human cognition. In the present work, we build on this result, and introduce a powerful radiation quantization scheme for human cognition. We show that the lack of independence of the Bose-Einstein statistics compared to the Maxwell-Boltzmann statistics can be explained by the presence of a 'meaning dynamics', which causes words to be attracted to the same words. And so words clump together in the same states, a phenomenon well known for photons in the early years of quantum mechanics, leading to fierce disagreements between Planck and Einstein. Using a simple example, we introduce all the elements to get a better and detailed view of this 'meaning dynamics', such as micro and macro states, and Maxwell-Boltzmann, Bose-Einstein and Fermi-Dirac numbers and weights, and compare this example and its graphs, with the radiation quantization scheme of a Winnie the Pooh story, also with its graphs. By connecting a concept directly to human experience, we show that entanglement is a necessity for preserving the 'meaning dynamics' we identified, and it becomes clear in what way Fermi-Dirac addresses human memory. Within the human mind, as a crucial aspect of memory, in spaces with internal parameters, identical words can nevertheless be assigned different states and hence realize locally and contextually the necessary distinctiveness, structured by a Pauli exclusion principle, for human thought to thrive.