Quantum locked time crystals and their effect warping space
Revised Chicago-Style Paper: "Quantum-Entangled Time Crystals and Their Application in Warp Drive Technology"
Title Page
Quantum-Entangled Time Crystals and Their Application in Warp Drive Technology
Dr. David Kawasaki, Ph.D.
Ludlow Institute of Advanced Theoretical Sciences
Published in Journal of Quantum Space-Time Engineering, Vol. 47, No. 2 (2075)
DOI: 10.1234/jqste.2075.472.123
Abstract
This paper investigates a warp drive powered by quantum-entangled time crystals embedded in crystalline matrices. Originally developed for faster-than-light (FTL) communication, these crystals reveal a secondary capability: when precisely aligned and quantum locked, their movement warps space-time locally. We propose a warp engine design—a 6-foot diameter, 24-foot long tube with 24 rows of time crystals—capable of sustaining FTL travel for up to six hours. This study details the theoretical basis, design mechanics, and limitations, underscoring its potential for interstellar exploration.
Introduction
Time crystals, theorized as quantum systems with periodic ground-state motion (Wilczek 2012), have matured into practical applications through stable, embedded forms. When produced as entangled pairs within a crystalline matrix, they enable FTL communication over distances up to 0.95 light years (Kawasaki 2035). A serendipitous finding—that moving perfectly aligned, quantum-locked time crystals bends space—has inspired a warp drive system. This paper, authored by Dr. David Kawasaki of the Ludlow Institute of Advanced Theoretical Sciences, elaborates on its principles and design.
Theoretical Framework
Quantum Entanglement and FTL Communication
Entangled time crystals, created simultaneously in matched pairs, facilitate FTL communication by leveraging quantum entanglement. Specialized software filters noise and decodes patterns across the crystal array, achieving a range of 0.95 light years despite low bandwidth (Russo & Patel 2074). A base-20 language encoded in a 20-crystal truncated icosahedron supports 1080pi video transmission (Kawasaki 2073).
Quantum Locking and Space-Time Manipulation
The warp effect stems from quantum locking: when 10 aligned time crystals were moved, they warped their surroundings, an effect dissipating over time. This space-time curvature, modeled as:
ΔS=α⋅ΔxN⋅(∑i=1Nmi⃗)\Delta \mathcal{S} = \frac{\alpha \cdot \Delta x}{N} \cdot \left( \sum_{i=1}^{N} \vec{m_i} \right)\Delta \mathcal{S} = \frac{\alpha \cdot \Delta x}{N} \cdot \left( \sum_{i=1}^{N} \vec{m_i} \right)
where
ΔS\Delta \mathcal{S}\Delta \mathcal{S}
is distortion,
α\alpha\alpha
is the locking coefficient,
Δx\Delta x\Delta x
is crystal displacement, (N) is the number of crystals, and
mi⃗\vec{m_i}\vec{m_i}
are motion vectors, enables FTL travel by contracting and expanding space (Kawasaki & Russo 2036).
Warp Engine Design
The engine is a 6-foot diameter, 24-foot long tube with 24 rows of time crystals mounted on precision CNC devices. An egg-shaped crew section connects to a bulbous rear engine via aerodynamic fins.
Key Features
Time Crystals: 24 rows of entangled crystals in protective matrices.
CNC Mounts: Enable nanometer-scale movements, forming an hourglass shape to generate the warp field.
Warp Mechanism: Crystals contract centrally and expand at the ends, sustaining the warp bubble during motion.
Operational Process
Align crystals for quantum locking.
Shift crystals into an hourglass configuration to activate the warp field.
Sustain warp for up to six hours, limited by crystal momentum.
Exit warp by stopping or rotating crystals to collapse the field.
References
Kawasaki, D. 2035. "FTL Communication via Embedded Time Crystals." Quantum Communications Letters 9 (1): 12–25.
Kawasaki, D., and T. Russo. 2035. "Quantum Locking and Space-Time Warping." Journal of Advanced Physics 42 (3): 123–145.
Russo, T., and R. Patel. 2035. "Pattern Recognition in Quantum-Entangled Crystals." Physical Review X 14 (2): 021045.
