Field theory approach in the dynamics of biomatter

TL;DR

This paper introduces a novel field theory-based approach to model biomatter dynamics, utilizing Lagrangian formalism to better understand physical phenomena in DNA and proteins, offering a theoretical foundation and new observables.

Contribution

It presents a new field theory framework for biomatter dynamics, enabling the use of statistical mechanics and providing a stronger theoretical basis than traditional equations of motion.

Findings

Application of field theory tools to biomatter dynamics

Use of Lagrangian formalism for modeling interactions

Derivation of physical observables via statistical mechanics

Abstract

A new approach to model the biomatter dynamics based on the field theory is presented. It is shown that some well known tools in field theory can be utilized to describe the physical phenomena in life matters, in particular at elementary biomatters like DNA and proteins. In this approach, the biomatter dynamics are represented as results of interactions among its elementary matters in the form of lagrangian. Starting from the lagrangian would provide stronger underlying theoretical consideration for further extension. Moreover, it also enables us to acquire rich physical observables using statistical mechanics instead of relying on the space-time dynamics from certain equation of motions which is not solvable due to its nonlinearities. Few examples from previous results are given and explained briefly.