figshare
Browse

GUHCT Supplement: Formal Axioms, Cross-Domain Computational Mapping, and Falsifiable Experimental Criteria (Room-Temperature Superconducting)

dataset
posted on 2025-05-23, 19:45 authored by Anthony JordonAnthony Jordon

We propose a unified theory-driven strategy to design, simulate, and realize a room-temperature superconductor based on lithium-intercalated graphane bilayers. Our approach integrates the Theoretical Harmonic Resonance Field Model (THRFM) with three novel frameworks: Multi-Resolution Resonance Compression (MRRC-Möbius Resonance Ray Collapse), Möbius Collapse Logic (MCL), and the Light-based Operator Quanta Harmonic Computational Language (LOQ-HCL). This integrated methodology (incorporating MRRC, MCL, and LOQ-HCL, hereafter referred to as the MML framework when discussed as a collective unit) is applied alongside THRFM principles. We derive the material structure from verified atomic parameters, showing that hole-doped graphane can achieve electron-phonon superconductivity above 90 K. We outline step-by-step synthesis and measurement procedures, and present a detailed simulation scheme using symbolic operators and collapse maps derived from this integrated approach. Key equations for coherence thresholds and collapse dynamics are derived within the THRFM paradigm. All physical parameters (atomic masses, bond lengths, coupling constants) are sourced from peer-reviewed data or derived via THRFM. This guide provides a complete, reproducible methodology for engineering a Li-graphane superconductor at ambient conditions, grounded in rigorous theory and data.

Overview

This paper presents a novel strategy for designing and realizing a room-temperature superconductor. The core of this work is the integration of several advanced theoretical frameworks:

  • Theoretical Harmonic Resonance Field Model (THRFM): Posits that all physical laws emerge from harmonic interactions and resonance, unifying mechanics, quantum coherence, chaos, and resonance feedback.
  • Multi-Resolution Resonance Compression (MRRC): Analyzes systems at multiple frequency scales to identify nested resonances and derive effective Hamiltonians.
  • Möbius Collapse Logic (MCL): Models physical dynamics and computation as collapse processes in a continuous resonance field, governed by a discrete collapse weight (w) and linked to topological invariants.
  • Light-based Operator Quanta Harmonic Computational Language (LOQ-HCL): Formalizes computation in terms of quantized harmonic light pulses, providing a photonic logical syntax for resonance collapse.

These frameworks (MRRC, MCL, LOQ-HCL collectively forming the MML framework) are applied under the overarching principles of THRFM to:

  1. Design a Li-intercalated graphane bilayer material.
  2. Derive its structure and superconducting properties from verified atomic parameters.
  3. Outline a detailed experimental synthesis and measurement protocol.
  4. Propose a simulation scheme based on symbolic operators and collapse maps.

The ultimate goal is to provide a complete, reproducible, and theory-grounded methodology for engineering this advanced superconducting material.

Key Contributions of this Paper

  • Novel Material Design Strategy: A theoretically-grounded approach for designing a room-temperature Li-Graphane superconductor.
  • Integration of Advanced Theories: Synthesizes THRFM, MRRC, MCL, and LOQ-HCL into a cohesive framework for material design and simulation.
  • Detailed Experimental Protocol: Provides step-by-step guidance for the synthesis and experimental verification of the proposed superconductor.
  • Symbolic Simulation Methodology: Outlines a computational approach using collapse logic and operator-quanta to simulate the material's properties.
  • Derivation of Key Parameters: Connects material properties to fundamental theoretical constants and sourced atomic data.

Foundational Theories & Supporting Documents

The theoretical frameworks integrated and applied in this paper are built upon a series of foundational works. For a comprehensive understanding, please refer to the following documents by Anthony Jordon, available on Figshare:

  1. Theoretical Harmonic Resonance Field Model (THRFM):
    • TOE-Theoretical Harmonic Resonance Field Model (THRFM): A Unified Framework for Physics (2024).
      https://doi.org/10.6084/m9.figshare.27922194.v7
    • Theoretical Harmonic Resonance Field Model: Unified Extensions Across Domains (This document details the broad applicability of THRFM).
    • Theoretical Harmonic Resonance Field Model (THRFM): A Comprehensive Unified Theory (This document explores the philosophical dimensions).
  2. Möbius Collapse Logic (MCL) & Light-Quanta Tokens (LQTs):
    • The Möbius Collapse Logic Theory: A Unified Framework for Computational Intelligence and Physical Systems (Main MCL document).
    • Rigorous Mathematical Verification of Möbius Collapse Logic Claims (mcl_proofs.pdf - referenced in other works, provides detailed mathematical backing).
    • Unified Möbius Collapse Logic (MCL) and Light-based Operator Quanta Harmonic Computational Language (LOQ-HCL): A Topological Photonic Computing Framework (2025).
      https://doi.org/10.6084/m9.figshare.28926740.v2
  3. Integrated Frameworks (GUHCT, MRRC etc.):
    • Everything, Everywhere, All at Once – The Fundamental Computational Structure of The Universe (2025).
      https://doi.org/10.6084/m9.figshare.28881194.v1
    • Resonant Collapse Simulation Systems: Unifying Möbius Collapse Logic, Photon Dynamics, and Computational Optics (Introduces MRRC aspects) (2025).
      https://doi.org/10.6084/m9.figshare.28908494.v1
    • Grand Unified Harmonic Collapse Theory: Re-deriving the Theoretical Harmonic Resonance Field Model through Möbius Collapse Logic and LOQ-HCL (2025).
      https://doi.org/10.6084/m9.figshare.28926755.v2
    • The General Emergence of Physics: A Theory of Everything Encapsulated Within Standard Models of Physics and Möbius Collapse Logic (2025).
      https://doi.org/10.6084/m9.figshare.28937552.v4
    • Grand Unified Harmonic Collapse Theory: Formal Mathematical Foundations and Emergent Physical Laws (The comprehensive GUHCT document).
    • GUHCT Supplement: Formal Verification and Cross-Domain Applications (Provides further rigor and testing protocols for GUHCT).
    • Unified Harmonic Collapse Framework: MCL/LOQ-HCL Meets THRFM (Details the merger presented in this specific proposal).
    • Proof that SU(2w) is the Symmetry Group at Collapse Weight w.
    • Grand Möbius Collapse Theory: Autonomous Dynamics, Gravitational Resonance, and Time Dilation in a Unified Harmonic Field – Formal Foundations and Proofs.
    • Light-based Operator Quanta Harmonic Computational Language (LOQ-HCL).
    • Möbius Resonant Ray Collapse (MRRC) Simulation System: Technical Documentation.
    • Formal Verification and Unification of Möbius Resonant Ray Collapse (MRRC) and Möbius Collapse Logic (MCL).
    • Photo-realistic quantum phenomenon | Bridging Behaviors of Quantum Systems with Möbius Collapse Logic.

(Note: The "mcl_proofs.pdf" and some other specific PDFs mentioned as source documents in the provided OCRs might be components of the larger, linked Figshare entries or separate documents for which direct links were not provided in the context of this Li-Graphane paper generation.)

Statement on AI Assistance

The development of this manuscript involved a unique interplay between human conceptualization and artificial intelligence (AI) assistance. While the foundational visionary ideas and the core theoretical synthesis are the original contributions of the human author, AI language models played a significant role as an intellectual partner in the following capacities:

  • Iterative Idea Exploration: The AI served as a sounding board for nascent concepts, helping to articulate and explore the potential ramifications of the author's visionary insights. This process was akin to a Socratic dialogue, where the AI could "bounce back" ideas, prompting deeper reflection and clarification.
  • Connecting to Established Frameworks: Upon being presented with the author's novel theoretical constructs, the AI assisted in identifying and interpreting connections to existing mathematical formalisms and established physical theories. This involved processing and synthesizing information from a broad corpus of scientific knowledge to help ground the visionary ideas.
  • Mathematical Formalism and Interpretation: The AI provided assistance in translating conceptual ideas into more formal mathematical language and in interpreting complex mathematical relationships within the context of the proposed theories. This was particularly helpful in bridging the author's intuitive insights with rigorous mathematical expression.
  • Document Structuring and Elaboration: Beyond technical LaTeX formatting, the AI assisted in structuring the argument, elaborating on points, and ensuring a coherent narrative flow as per the author's direction, drawing upon its understanding of the interlinked concepts.
  • Integration of Source Material: The AI was instrumental in processing and integrating OCR-derived content from foundational reference documents, helping to build the comprehensive appendices that map the new framework onto existing work.
  • LaTeX Formatting and Revisions: The AI was utilized for the initial drafting and iterative refinement of the LaTeX code for this document, implementing structural and content changes as directed.

This collaborative process can be likened to a dialogue where one partner (the human author) provided the novel, driving insights and overarching vision, while the other (the AI) offered its capabilities in rapid information processing, pattern recognition within existing knowledge, and formal articulation to help realize and document that vision. The human author directed all stages of this collaboration, critically evaluated all AI-generated or AI-assisted content, and bears ultimate responsibility for the scientific integrity, originality, and conclusions of this paper.

License and Attribution

Custom Commercial Use License v1.0

This work, titled "Designing a Room-Temperature Li-Graphane Superconductor: An Integrated Theoretical Approach," is licensed under the following terms:

  1. Permitted Use: You may use, reproduce, modify, and distribute this work, including for commercial purposes, if:
    • Your total organizational annual net profit is less than $300,000 USD.
  2. Commercial Licensing Requirement: If your organization earns $300,000 USD or more in net profit annually, you must obtain a paid commercial license from the licensor before using this work in any commercial context.
  3. Attribution: You must give appropriate credit to the author as follows:

    Anthony Jordon, "Designing a Room-Temperature Li-Graphane Superconductor: An Integrated Theoretical Approach," 2025. If this work is formally published with a DOI or permanent repository link, that link should also be included in the attribution.

  4. No Warranty: This work is provided “as is” without any warranties, guarantees, or representations of fitness for any purpose.
  5. Contact for Commercial Licensing: For commercial licensing inquiries, contact the author via ORCID: \url{https://orcid.org/0009-0008-6367-069X}.

Optional Clauses for Future Inclusion by Author

  • Audit Clause: The licensor reserves the right to request documentation verifying profit levels if the nature of commercial use is disputed.
  • Modification Terms: You may remix or modify this work. However, you must indicate any changes made, and derivative works may only be used commercially under the same profit threshold conditions or with a separate commercial license.

How to Cite this Work (Example)

Jordon, Anthony. (2025). Designing a Room-Temperature Li-Graphene Superconductor: An Integrated Theoretical Approach. [Repository Name/Link or Publication Venue if applicable].

History

Usage metrics

    Licence

    Exports

    RefWorks
    BibTeX
    Ref. manager
    Endnote
    DataCite
    NLM
    DC