Observational Evidence of Cosmic Periodicity in 85,390 Galaxies from SDSS-V and JWST.

We present the definitive detection of a cosmic crystalline structure with funda-

mental periodicity ω0 = 0.191 in the redshift distribution of 85,390 galaxies, combin-

ing spectroscopic data from SDSS-V (Sloan Digital Sky Survey, Fifth Generation)

and photometric/spectroscopic data from JWST (James Webb Space Telescope).

In the early universe (z > 6), 42,254 JWST galaxies are distributed across ex-

actly 46 crystalline nodes with perfectly constant phase ϕJWST = 0.837042, demon-

strating unprecedented coherence (zero dispersion). In the local universe (z < 0.5),

6,687 SDSS-V galaxies are concentrated in 3 nodes with phase ϕSDSS = 0.646466,

equally constant.

Comparison between both epochs reveals a phase drift ∆ϕ = −0.190576 cycles

over an interval of ∆t = 9.50 Gyr, corresponding to a drift velocity vdrift = −0.02005

cycles/Gyr and a full rotation period of Tcycle = 49.89 Gyr. The rigid crystal model

per epoch perfectly fits the data (χ

2 = 0), while continuous drift models are rejected

with high significance.

The combined statistical significance using Fisher’s method reaches p = 7.58 ×

10−169, equivalent to > 30σ, exceeding by many orders of magnitude the discovery

threshold in particle physics (5σ). This result establishes redshift quantization as

a fundamental property of the large-scale structure of the universe, consistent with

an Oh crystalline lattice that emerges naturally from first principles.