STUPIDITY THEORY and the Nature of Reality

What is Time? What is Consciousness? What is Light? What is Gravity? These are BIG, UNANSWERED questions. We have hit a dead-end deriving conscious experience from the current deterministic models we use.

In this video I explain a few theories and show how they are related, including "Stupidity Theory," invented just now!

Thanks for watching, liking, and subscribing! It really helps the channel.
Support the channel at Patreon.com/chrislehto and watch this video early and AD-Free!
Join the UAP Society Discord server
UAPsociety.com

This is a copy paste from the ChatGPT discussion I had after I made the video-
CHATGPT

Ilya Prigogine was awarded the Nobel Prize in Chemistry in 1977 for his contributions to the understanding of the thermodynamics of non-equilibrium systems. His work focused on the behavior of complex systems that are far from equilibrium, such as chemical reactions, biological systems, and even the universe itself.

Prigogine developed a new approach to thermodynamics that is now known as "non-equilibrium thermodynamics." This approach takes into account the effects of time, irreversibility, and fluctuations on the behavior of complex systems, which are not well-described by traditional equilibrium thermodynamics. He proposed that far from equilibrium, the dynamics of a system can lead to self-organization and the emergence of new structures and patterns.

One of Prigogine's most significant contributions was the development of the theory of dissipative structures. According to this theory, a far-from-equilibrium system can spontaneously organize itself into a structure that dissipates energy and maintains a stable, non-equilibrium state. These structures can be seen in a wide range of natural and artificial systems, including chemical reactions, turbulence, and even social organizations.

Prigogine's work has had a significant impact on a wide range of fields, including chemistry, physics, biology, and engineering. Over the years, his model has continued to evolve as new discoveries have been made in these fields. Prigogine himself continued to work on the study of complex systems throughout his career and made significant contributions to our understanding of the behavior of far-from-equilibrium systems.

In terms of his views on non-equilibrium, Prigogine remained a proponent of the idea that the dynamics of complex systems far from equilibrium could lead to the emergence of new structures and patterns. He also emphasized the importance of understanding the role of fluctuations and the irreversibility of time in these systems. However, as new research has been conducted in this field, other scientists have proposed different approaches and models for understanding non-equilibrium systems, and the field continues to evolve.

How does his understanding of Entropy play into current physics? Could we be missing irreversibility thermodynamics that could help explain life?

RESPONSE

Prigogine's understanding of entropy and irreversibility has had a significant impact on current physics, particularly in the study of complex systems far from equilibrium. His work showed that entropy production can play a crucial role in the behavior of these systems and that traditional equilibrium thermodynamics is not sufficient to describe their behavior. In his view, entropy production is intimately connected with the emergence of new structures and patterns in these systems.

Current physics continues to investigate the role of entropy and irreversibility in the behavior of complex systems, particularly in the study of non-equilibrium systems such as living cells, biological systems, and ecological systems. These systems exhibit behavior that cannot be fully explained by traditional equilibrium thermodynamics, and non-equilibrium thermodynamics is now considered an essential tool for understanding their behavior.

The study of irreversibility thermodynamics has the potential to help explain life, as living systems are far-from-equilibrium systems that exhibit complex behavior. Some scientists have suggested that the emergence of life itself may be a consequence of non-equilibrium dynamics, and that understanding the thermodynamics of these systems may be key to understanding the origin and evolution of life on Earth.

However, while the study of non-equilibrium thermodynamics has led to significant advances in our understanding of complex systems, it remains an active area of research, and there is still much to be learned about the behavior of these systems. While it is possible that irreversibility thermodynamics may help explain life, it is also likely that other factors, such as self-organization, information processing, and the emergence of complexity, play important roles as well.