The Heisenberg limit at cosmological scales
Abstract
For an observation time equal to the universe age, the Heisenberg principle fixes the value of the smallest measurable mass at m H=1.35 × 10-69 kg and prevents to probe the masslessness for any particle using a balance. The corresponding reduced Compton length to m H is λbar H, and represents the length limit beyond which masslessness cannot be proved using a metre ruler. In turns, λbar H is equated to the luminosity distance d H which corresponds to a red shift z H. When using the Concordance-Model parameters, we get d H = 8.4 Gpc and z H=1.3. Remarkably, d H falls quite short to the radius of the observable universe. According to this result, tensions in cosmological parameters could be nothing else but due to comparing data inside and beyond z H. Finally, in terms of quantum quantities, the expansion constant H0 reveals to be one order of magnitude above the smallest measurable energy, divided by the Planck constant
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