What question did this study set out to answer?

The aim is to create a unified framework linking quantum information with dark matter and dark energy dynamics.

March 18, 2026Open Access

Tesseract Quantum Temporal Inversion (TQTI): A Unified Information-Theoretic Framework for Dark Matter, Dark Energy, Wormhole Dynamics, and Quantum Gravity

Key Points

The aim is to create a unified framework linking quantum information with dark matter and dark energy dynamics.
Developed the Tesseract Quantum Temporal Inversion (TQTI) framework
Applied Landauer's Principle and mass-energy equivalence
Derived mass from lost quantum bits
Reinterpreted Einstein-Rosen bridges
Utilized observational data from ESA Planck CMB and IBM experiments.
Calculated mass per lost bit as 2.90 × 10⁻⁴⁰ kg
Founded dark matter mass estimation on 3.4 × 10⁹³ bits
Obtained cosmological constant Λ_TQTI = 4.57 × 10⁻⁵³ m⁻²
Demonstrated re-interpretation of Einstein-Rosen bridges as Archive Synchronisation Channels

Abstract

This paper presents the Tesseract Quantum Temporal Inversion (TQTI) framework, proposing that permanently decohered quantum information accumulates gravitational mass constituting dark matter. From Landauer's Principle and mass-energy equivalence, we derive Mbit = 2. 90 × 10⁻⁴⁰ kg per lost bit. Integration yields 3. 4 × 10⁹³ bits reproducing observed dark matter mass. A first-principles cosmological constant derivation yields ΛTQTI = 4. 57 × 10⁻⁵³ m⁻², within factor 2. 4 of observation. Einstein-Rosen bridges are reinterpreted as Archive Synchronisation Channels. ESA Planck CMB data and Chandrasekhar dynamical friction provide observational support. Six IBM 127-qubit hardware experiments provide empirical motivation.

Tesseract Quantum Temporal Inversion (TQTI): A Unified Information-Theoretic Framework for Dark Matter, Dark Energy, Wormhole Dynamics, and Quantum Gravity

Key Points

Abstract

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