AI Article Synopsis
- There is an expectation that classical physics laws can explain biological processes, especially in the brain, by examining energy and information exchange through emotional responses.
- The study employs thermodynamic principles, particularly the Carnot cycle, to analyze how different emotional states—positive and negative—impact the brain’s energy dynamics and mental energy.
- The findings suggest that the mathematical framework of the Carnot cycles could help solidify psychology as a scientific discipline by linking emotional states to their respective energetic and entropic consequences.
Article Abstract
There is a general expectation that the laws of classical physics must apply to biology, particularly the neural system. The evoked cycle represents the brain's energy/information exchange with the physical environment through stimulus. Therefore, the thermodynamics of emotions might elucidate the neurological origin of intellectual evolution, and explain the psychological and health consequences of positive and negative emotional states based on their energy profiles. We utilized the Carnot cycle and Landauer's principle to analyze the energetic consequences of the brain's resting and evoked states during and after various cognitive states. Namely, positive emotional states can be represented by the reversed Carnot cycle, whereas negative emotional reactions trigger the Carnot cycle. The two conditions have contrasting energetic and entropic aftereffects with consequences for mental energy. The mathematics of the Carnot and reversed Carnot cycles, which can explain recent findings in human psychology, might be constructive in the scientific endeavor in turning psychology into hard science.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7843413 | PMC |
| http://dx.doi.org/10.1016/j.csbj.2021.01.008 | DOI Listing |
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