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Innovative Approaches to Overcome Thermodynamics Limits: Cutting-Edge Research Discoveries

Explore groundbreaking methods that challenge the Second Law of Thermodynamics, such as Maxwell’s Demon and Asymmetrical Atomic Processes, with insights from renowned researchers in the field. Uncover possibilities in thermoelectrics, superconductivity, and more.

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Innovative Approaches to Overcome Thermodynamics Limits: Cutting-Edge Research Discoveries

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  1. Methods that Circumvent the Second Law of Thermodynamics Maxwell’s Demon: the Proell effect Atmospheric gravity separator: Chas. Steinmetz @ GE Asymmetrical mechanical processes: Herb Johnson Asymmetrical atomic processes: thermoelectrics, Daniel Sheehan at the University of San Diego Asymmetrical atomic processes: superconductivity, Peter Keefe at the University of Detroit Mercy Asymmetrical atomic processes: inverted populations of phase space, Steven Smith’s magnetothermodynamics @ www.geocities.com/electrogravitics Asymmetrical atomic processes: infrared photovoltaics Gibbs Free Energy changes: G = H – TS

  2. Methods that Circumvent the Second Law of Thermodynamics Maxwell’s Demon: the Proell effect Atmospheric gravity separator: Chas. Steinmetz @ GE Asymmetrical mechanical processes: Herb Johnson Asymmetrical atomic processes: thermoelectrics, Daniel Sheehan at the University of San Diego Asymmetrical atomic processes: superconductivity, Peter Keefe at the University of Detroit Mercy Asymmetrical atomic processes: inverted populations of phase space, Steven Smith’s magnetothermodynamics @ www.geocities.com/electrogravitics Asymmetrical atomic processes: infrared photovoltaics Gibbs Free Energy changes: G = H – TS

  3. Methods that Circumvent the Second Law of Thermodynamics Maxwell’s Demon: the Proell effect Atmospheric gravity separator: Chas. Steinmetz @ GE Asymmetrical mechanical processes: Herb Johnson Asymmetrical atomic processes: thermoelectrics, Daniel Sheehan at the University of San Diego Asymmetrical atomic processes: superconductivity, Peter Keefe at the University of Detroit Mercy Asymmetrical atomic processes: inverted populations of phase space, Steven Smith’s magnetothermodynamics @ www.geocities.com/electrogravitics Asymmetrical atomic processes: infrared photovoltaics Gibbs Free Energy changes: G = H – TS

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