D-Brane Holographic Screens: Thermodynamic Interfaces in Information Processing Networks

Abstract

Bryce Weiner

We present a comprehensive framework for understanding D-branes as holographic screens within the recently established information processing architecture governed by γ = 1.89 × 10−29 s−1. Event horizons, cosmic screens, and other thermodynamic boundaries manifest as D-branes characterized by the tensor Dμν that governs information encoding through dual E8×E8 network architecture. The D-brane tension TD = (I/Imax)2 provides a precise measure of information saturation at holographic boundaries, reaching unity at the holographic bound where phase transitions occur. Our framework reveals that D-branes function as active thermodynamic interfaces rather than passive geometric surfaces, with boundary-localized information encoding directly on the D-brane surface and non-local correlations extending through network connectivity. We derive the complete mathematical formalism for D-brane dynamics, including evolution equations for the D-brane tensor, boundary conditions for information flux, and coupling mechanisms to spacetime curvature. The framework predicts distinctive observational signatures including gravitational wave memory effects from D-brane interactions, modified polarization patterns in gravitational lensing, specific correlation structures in laboratory analogs, and novel phenomena in cosmological surveys. These predictions provide multiple pathways for experimental validation using current and next-generation observational capabilities, establishing D-brane holographic screens as a fundamental component of information-theoretic physics.

PDF