Biophoton emission in the evolution of a squeezed state of frequency stable damped oscillator

Abstract. BACKGROUND:Propagation of photon signals in biological systems, such as neurons, accompanies the production of biophotons. The role of biophotons in a cell deserves special attention because it can be applied to diverse optical systems. OBJECTIVE: This work has been aimed to investigate the time behavior of biophoton signals emitted from living systems in detail, by introducing a Hamiltonian that describes the process. The ratio of the energy loss during signal dissipation will also be investigated. METHOD: To see the adiabatic properties of the biophoton signal, we introduced an adiabatic invariant of the system according to the method of its basic formulation. RESULTS: The energy of the released biophoton dissipates over time in a somewhat intricate way when t is small. However, after a sufficient long time, it dissipates in proportion (1 + λ0t) 2 to where λ0 is a constant that is relevant to the degree of dissipation. We have confirmed that the energy of the biophoton signal oscillates in a particular way while it dissipates. CONCLUSION: This research clarifies the characteristics of radiation fields associated with biophotons on the basis of Hamiltonian dynamics which describes phenomenological aspects of biophotons signals.

show abstract

“…[8,9,36,42]. The analysis of photon energy based on the adiabatic invariant also gives the same results.…”

Section: S583supporting

confidence: 58%

“…According to the relaxation behavior of the signal, many different formulae of the Hamiltonian for describing radiation fields are allowed [36]. Among various kinds of relaxation behaviors, the one that corresponds to a frequency stable damped harmonic oscillator may be the most typically known one.…”

Section: Analysis Of a Biophoton Signalmentioning

confidence: 99%

Classical analysis of time behavior of radiation fields associated with biophoton signals

Choi

Kim

Sever

et al. 2016

THC

View full text Add to dashboard Cite

show abstract

“…Squeezed states they used are not as general as the ones of [138]. given in the paper is not real when α is not real.…”

Section: [8]mentioning

confidence: 96%

Biophotons, coherence and photocount statistics: A critical review

Cifra

Brouder

Nerudová

et al. 2015

Journal of Luminescence

View full text Add to dashboard Cite

Biological samples continuously emit ultra-weak photon emission (UPE, or "biophotons") which stems from electronic excited states generated chemically during oxidative metabolism and stress. Thus, UPE can potentially serve as a method for noninvasive diagnostics of oxidative processes or, if discovered, also of other processes capable of electron excitation. While the fundamental generating mechanisms of UPE are fairly elucidated together with their approximate ranges of intensities and spectra, statistical properties of UPE is still a highly challenging topic. Here we review claims about nontrivial statistical properties of UPE, such as coherence and squeezed states of light. After introduction to the necessary theory, we categorize the experimental works of all authors to those with solid, conventional interpretation and those with unconventional and even speculative interpretation. The conclusion of our review is twofold; while the phenomenon of UPE from biological systems can be considered experimentally well established, no reliable evidence for the coherence or nonclassicality of UPE was actually achieved up to now. Furthermore, we propose perspective avenues in the research of statistical properties of biological UPE.

show abstract

“…Additional information about quantum coherence in the Investigations with the light induced biophoton signals have remained confined to models that aim to explain decay shape and extract strength parameters [10], and do not explicitly address the problem of coherence and its nature. The model analysed here addresses these important issues and is henceforth called quantum model [14,15]. The quantum model does so explicitly by assigning an evolving quantum squeezed state to every response signal [16].…”

Section: Quantum Coherence Of Signals Emitted In Response To Stimulationmentioning

confidence: 99%

“…The parameter o is not a property of signal and expected to be same in all signals. This model embraces a classical description[3].SThe functional form of n(t) in the quantum model[15] is…”

mentioning

confidence: 99%

Hints at Quantum Characteristics of Light Signals Measured from a Human Subject

Racine¹,

Rastogi²,

Bajpai³

2013

View full text Add to dashboard Cite

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.

show abstract

Biophoton emission in the evolution of a squeezed state of frequency stable damped oscillator

Cited by 19 publications

References 15 publications

Classical analysis of time behavior of radiation fields associated with biophoton signals

Classical analysis of time behavior of radiation fields associated with biophoton signals

Biophotons, coherence and photocount statistics: A critical review

Hints at Quantum Characteristics of Light Signals Measured from a Human Subject

Contact Info

Product

Resources

About