Jaxian Dynamics:
Toward An Artificial Fourth Law Of Thermodynamics
Revolutionary breakthrough in Entropic Systems Mathematics redefines the fundamental laws of physics, transforming entropy from an unavoidable fate into a controllable design variable.
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Scientific Abstract
Recent advances in quantum operator theory reveal that entropy growth is not purely random but structured by hidden conservation laws. Building on this framework, we introduce Jaxian Dynamics, the founding discipline of Entropic Systems Mathematics. This discipline reframes entropy as a controllable design variable rather than an unavoidable fate.

We formalize a set of Artificial Laws of Thermodynamics, culminating in a Fourth Law: Information Is Energy. We show how engineered operator control can steer equilibrium, orchestrate energy pathways, and stabilize ordered states at low energies. Finally, we outline applied realizations in autonomous energy systems, photonic compute, and resilient communications, under the branded framework of QEntropy™.
Author: Jackson P. Hamiter
Research Paper Outline
01
Introduction — Limits of classical thermodynamics
Exploring the boundaries of traditional thermodynamic principles and the need for new frameworks.
02
Theoretical Background — Operator dynamics, entropy control
Foundation of quantum operator theory and entropy manipulation mechanisms.
03
Jaxian Dynamics — Definition & scope as Entropic Systems Mathematics
Comprehensive introduction to the new discipline and its mathematical framework.
04
Artificial Laws of Thermodynamics (Zeroth+ to Fourth)
Formalization of extended thermodynamic laws including the revolutionary Fourth Law.
05
Experimental Validation Pathways (system KPIs, non-sensitive)
Methodology for testing and validating theoretical predictions.
06
Applications — Energy, compute, networks
Real-world implementations across multiple technological domains.
07
Conclusion — Toward an engineered physics of endurance
Future implications and the path forward for applied physics.
Press & Investor Brief
NEUJAX Unveils QEntropy™: The First Applied Law Beyond Thermodynamics
Science
Jaxian Dynamics extends thermodynamics into Entropic Systems Mathematics.
Breakthrough
Entropy becomes controllable; information is recognized as energy.
Applications
Never-landing drones, self-powered satellites, resilient micro-grids, energy-aware AI compute.
"As Newton gave way to Einstein, thermodynamics now evolves into Jaxian Dynamics — and QEntropy™ is its applied realization."
Experimental Validation Plan
Key Performance Indicators (KPIs)
Entropy-rate modulation
Statistical entropy curves vs. uncontrolled baselines
Wh/kg endurance extension
Performance metrics in drones/UAVs
Joules per inference
PhotoniQ vs. CMOS efficiency comparison
Stability persistence
Low-energy oscillation maintenance
Experimental Testbeds & Methods
Testbeds:
  • Portable hybrid energy modules (PV + alternator + orchestrated storage)
  • Drone flight endurance trials
  • Photonic compute inference benchmarks
  • Thermal gradient to energy yield (controlled TEG experiments)
Methods:
  • Comparative baseline/control testing
  • Operator steering models validated by data regression
  • Independent lab third-party verification before publication
High-Impact Visuals Pack
Classical vs. Jaxian Laws Table
Comparative analysis of traditional thermodynamic laws versus the new Artificial Laws of Thermodynamics — already generated.
QEntropy Stack Diagram
Layered architecture: energy harvesters → entropy-control power stages → PhotoniQ/QSI → Orchestral-Q → applications.
Never-landing Drone Visual
Drone with solar skin + alternator pods + "QEntropy Core" glowing icon.
Entropy Curve Illustration
Classical: monotonic rise; Jaxian: modulated/controlled curve with oscillations.
Publication Roadmap
Target Journals:
  • Physical Review X (theory, citing Buča)
  • Nature Physics (discipline launch piece)
  • Nature Energy (applied hybrid systems)
  • Science Advances (multi-source power & entropy framing)
Target Conferences:
  • APS March Meeting (physics audience)
  • IEEE Energy Conversion Congress (engineering audience)
  • SPIE Photonics West (compute + photonics)
  • AIAA Aviation / ASCEND (aerospace/defense tie-ins)
Implementation Timeline
1
Month 0–3
File provisional patents
2
Month 3–6
Submit first public-safe theory paper (PRX/Nature Physics)
3
Month 6–12
Submit applied engineering validation (Nature Energy / Science Advances)
4
Month 12+
Conference rollouts
Timeline aligned with IP filings to ensure maximum protection while advancing scientific knowledge and commercial applications of QEntropy™ technology.