Theoretical Study of the Hard Photons Flow Emission Rate at $s\bar b\to\gamma g$ Systems in Annihilation Processes in One Loop

TL;DR

This paper provides a theoretical analysis of the hard photon flow emission rate in $sar{b} o \gamma g$ quark systems during annihilation processes, considering quantum field theory and various physical parameters.

Contribution

It introduces a quantum model for calculating the photon flow emission rate in high-energy quark annihilation processes at one-loop level, incorporating multiple physical parameters.

Findings

Photon flow rate increases with temperature and fugacity.

Photon flow rate decreases with activation coupling strength and critical temperature.

Rate depends on quantum parameters and thermal conditions.

Abstract

In this paper, we evaluate and analyze hard photons flow emission at $s\bar b\to\gamma g$ quarks system interaction in annihilation processes due to a quantum field theory in high energy physics. Two quantum wave vectors are assumed to localize quark and anti-quark in quantum space for higher thermal energy system. Quantum postulate theory and perturbative theory take into account the photonic flow emission rate that gets produced according to quantum model. The photonic flow rate is evaluated depending on physical parameters: activation coupling strength, electric charge of quark system, fugacity, transition momentum, quantum color number, photonic energies, total charge quark system, Euler factor, critical temperature and temperature of the quarks system. The photonic flow rate for $s\bar b\to\gamma g$ quarks system production in one loop Annihilation processes depends on the activation coupling strength, thermal energy, critical temperature, and fugacity. The rate increases with decreases in activation coupling strength and the critical temperature and with increases in the temperature and vice versa. However, the photonic flow rate increases with the fugacity at one-loop based on Juttner distribution and vice versa.