Holographic Quantum Communication: A Galactic-Scale Instantaneous Network Using qCA Sub-Regions and Diamond-Based Backup in the Radial AdS/CFT Model
A plan for starship communication systems and backup systems
This paper presents a holographic quantum communication system enabling
instantaneous data transfer across galactic distances within the radial AdS/CFT
model, where the universe is a Kerr black hole with a 2D quantum cellular automa-
ton (qCA) on an event horizon (EH) of radius rh ≈ 1.48 × 10^25 m, comprising N ≈
10^95 cells (area ∼ 2.27 × 10−41 m^2, parent Planck length Lpp ≈ 10^−20 m) and entropy
S ≈ 10^120 nats (child Planck length Lcp ≈ 10^−35 m). Earth continuously monitors
pre-designated qCA sub-regions, serving as “phone numbers,” allowing starships to
“dial home” from any galactic location by entangling with these sub-regions using
room-temperature silicon carbide (SiC) wafers integrated with plasmon-enhanced
grafold surfaces. The system achieves data rates of ∼ 6.72 × 10^52 bits/s for a 1
m2 device, with negligible entropy cost (∼ 7.25 × 10^40 nats, ∼ 10^−80 of S), en-
suring no perturbation to cosmological observables (e.g., CMB non-Gaussianity
fNL ≈ 1.1 − 1.5, large-scale structure σ8 ≈ 0.812 − 0.815). A backup system using
synthetic diamonds with pre-entangled nitrogen-vacancy (NV) centers provides re-
silience against hostile interference (e.g., sub-region scrambling). We detail Earth’s
continuous monitoring strategy, dynamic sub-region switching to counter attacks
without resorting to the diamond backup, and derive the system’s equations, com-
paring SiC and diamond approaches. The system aligns with JWST 2025, Planck
2018, and DES 2022 data, offering a robust framework for galaxy-wide communi-
cation.
