Biological electric fields and rate equations for biophotons

M Alvermann, Y N Srivastava, J Swain, A Widom

biophotons Electric fields Nonlinear rate equations

Key takeaways

01Biophoton intensity depends on biological electric fields
02The decay of this light is not a simple exponential curve
03Simple linear equations are inadequate for modeling this process
04Nonlinear rate equations may offer a more accurate model

The intensity of light emitted by living tissue is related to its internal electric fields and requires complex models to describe its behavior.

Abstract

Biophoton intensities depend upon the squared modulus of the electric field. Hence, we first make some general estimates about the inherent electric fields within various biosystems. Generally, these intensities do not follow a simple exponential decay law. After a brief discussion on the inapplicability of a linear rate equation that leads to strict exponential decay, we study other, nonlinear rate equations that have been successfully used for biosystems along with their physical origins when available.

Cite this study

APA: M Alvermann, Y N Srivastava, J Swain, & A Widom (2015). Biological electric fields and rate equations for biophotons. https://fasciaresearchdatabase.com/biological-electric-fields-and-rate-equations-for-biophotons/
MLA: M Alvermann, et al. "Biological electric fields and rate equations for biophotons." 2015, https://fasciaresearchdatabase.com/biological-electric-fields-and-rate-equations-for-biophotons/.
Chicago: M Alvermann et al. 2015. "Biological electric fields and rate equations for biophotons.". https://fasciaresearchdatabase.com/biological-electric-fields-and-rate-equations-for-biophotons/