This paper computes the complete information-thermodynamic signature of all 118 elements, revealing that log₁₀ (T) - log₁₀ (m) ≈ 39. 97 for every atom, where T is the temperature at which one bit carries energy equal to the element's rest mass. The Infoton Identity constant means atomic mass, de Broglie wavelength, and information content are mathematically interconvertible. Each element encodes as v = log₁₀ (m), log₁₀ (T), log₁₀ (λ), 1ᵀ, transforming the periodic table into a computational matrix where operations on all 118 elements execute simultaneously. Diffraction at d = 100λC recovers mass from wavelength, proving bidirectional conversion between chemistry and quantum mechanics. Energy ratios Eₑlement/Eₘito connect atomic physics to mitochondrial ATP synthesis thresholds. For biochemists: this explains why specific elements enable electron transport at physiological voltages. For neuroscientists: why ion channels select specific atoms at specific membrane potentials. For physicists: the unification of Landauer's principle, E = mc², and λ = h/p into one framework. Four tables provide the complete computational periodic table: mass-energy-information properties, wavelength-vector mappings, diffraction parameters, and bioenergetic ratios for all elements.
January Walker (Sun,) studied this question.