Abstract
We measure ultra-weak photon signals emitted from the hand of a human subject, either spontaneously or gradually decaying after local stress has been induced with five concentrations of H2O2. We analyze the photon distributions of both spontaneous and stimulated number of photons per measuring interval (bin sizes) according to statistics measure Fano Factor which leads to quantum optics, g(2)(0). We also fit either semi-classical based exponential or quantum grounded hyperbolic curves to the decays. Both indicators point towards an adequate description of the photon signal in an interpretation that is quantum. We extend the interpretation towards the suggestion of a quantum coherent aspect of the subject which, once placed in a therapeutic perspective, links to the holistic views on health.
Highlights
The phenomenon of spontaneous and incessant emission of, mainly visible range, photons by all living systems defies conventional interpretation
We measure ultra-weak photon signals emitted from the hand of a human subject, either spontaneously or gradually decaying after local stress has been induced with five concentrations of H2O2
A biophoton signal has many features which defy common interpretations in the living system. Two of these features are the visible range of photons and non-decaying nature of signal. Both features make the incorporation of biophoton emission in theclassical framework difficult
Summary
The phenomenon of spontaneous and incessant emission of, mainly visible range, photons by all living systems defies conventional interpretation. A biophoton signal has many features which defy common interpretations in the living system Two of these features are the visible range of photons (above the currency of biochemical energy) and non-decaying nature of signal. Both features make the incorporation of biophoton emission in the (semi)classical framework difficult. They cause and manifest all biological processes [2] They emit photon signal in probabilistic transitions from higher to lower energy states. A non-decaying signal requires coordinated and continuous replenishing of the population of biomolecules in higher energy state through a mechanism, which in case of biophoton signals remains operative at all time. We present analysis of biophoton signal emitted either spontaneously or after chemically-induced stress
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