PAPERS
11 preprints
Precision Lattice Entanglement Entropy
Methods, convergence, and the universal scaling function
This paper measures the fundamental constants of quantum entanglement on a computer lattice — with enough precision to make or break the dark energy prediction.
α_s precision
Richardson extrapolation · 4 sig figs
Cosmological Constant from Entanglement Entropy
A derivation via Jacobson-Cai-Kim horizon thermodynamics
This paper calculates the strength of dark energy from first principles — and gets an answer within 3% of what astronomers actually observe, with zero adjustable constants.
Λ_pred / Λ_obs
Zero free parameters · 3% gap
Einstein's Equations from Information Capacity
Capacity-metric duality and the Clausius derivation
This paper shows that gravity — the force that holds you to the Earth and bends light around black holes — is a consequence of how information flows through space.
Unique solution
Clausius residual = 0 iff Einstein
Why the Bare Cosmological Constant Vanishes
Five convergent proofs from entanglement entropy
This paper proves that vacuum energy does not generate a separate cosmological constant — because it was already gravity all along.
|Λ_bare| / Λ_ent bound
Five independent proofs · zero free parameters
Zero-Parameter Cosmological Concordance
From entanglement entropy to 28 observables
This paper takes one predicted number — the strength of dark energy — and checks it against every major astronomical measurement available. It fits the data better than the standard model of cosmology, despite having one fewer adjustable constant.
Bayes factor vs ΛCDM
28 observables · zero free parameters
The Standard Model from the Cosmological Constant
Gauge group uniqueness and the graviton edge-mode fraction
This paper shows that the strength of dark energy — a single number — uniquely determines which particles exist in nature, why there are three generations of matter, and that neutrinos have Majorana mass.
The Cosmological Constant as a Particle Detector
Mass-independent BSM constraints from entanglement entropy
This paper treats the cosmological constant as a particle detector that can see every particle in nature regardless of its mass — and uses it to test 20 theories of new physics.
Deriving Einstein's Equations on Causal Sets
From discrete structure to continuum gravity
This paper asks: what if space and time are not smooth, but made of tiny discrete points — can gravity still emerge? The answer is yes.
Thermodynamic Equilibrium and the Cost of Modifying General Relativity
Uniqueness theorems and EFT constraints from horizon entropy production
This paper proves that Einstein's theory of gravity is the only theory that keeps the universe in thermodynamic balance — and uses that to rule out almost all competing theories.
Why 3+1 Dimensions and Why von Neumann
Selection principles for the cosmological constant
This paper proves that three spatial dimensions and one time dimension is the only setup where dark energy can arise from entanglement — and explains why the standard measure of quantum information is the right one.
DESI Confrontation and Zero-Parameter Cosmological Scorecard
Systematic observational tests of the entanglement entropy framework
This paper stress-tests the dark energy prediction against every major cosmological dataset — and finds the biggest threat comes from supernovae, not from the DESI experiment itself.