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April 25, 2026Open Access

The Blackbody Constant of Information-Energy

Key Points

The aim is to establish a new universal dimensionless constant connecting information-energy erasure to thermal radiation.
Derived the mass equivalent of information-energy erasure related to temperature.
Calculated the Landauer erasure frequency and related it to the blackbody peak frequency.
Identified the universal constant Λ_LW as independent of temperature and material.
Derived Λ_LW = ln(2) / x freq = 0.24567147797282315, an irrational dimensionless constant.
Demonstrated Λ_LW holds constant across 41 orders of magnitude of temperature.
Established that the frequency for erasing one bit of information-energy is at 24.567% of the blackbody peak frequency.

Abstract

I propose ΛLW, a previously unrecognized universal dimensionless constant connecting information-energy erasure to thermal radiation. Beginning from m (T) =kBTln (2) / c² which establishes that one bit of information-energy erasure has a mass equivalent scaling linearly with temperature, I recover the Landauer erasure frequency νL = kBTln2/h and divide by the blackbody peak frequency from Wien's Displacement Law νBlackBody, peak = kBT⋅xfreq/h. The temperature, Boltzmann constant, and Planck constant cancel simultaneously, yielding ΛLW = ln (2) / x freq = 0. 24567147797282315. . . The constant is irrational, non-repeating, dimensionless, and independent of temperature, material, and observer. ΛLW holds across 41 orders of magnitude of temperature without deviation. The minimum frequency at which one bit of information-energy can be erased is permanently located at 24. 567% of the blackbody peak frequency of any thermal environment in the universe. The individual components are well established. Their combination and interpretation as a universal constant are new.

The Blackbody Constant of Information-Energy

Key Points

Abstract

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