Study Of The Fundamental Physical Principles in Atmospheric Modeling Based On Identification Of Atmosphere - Climate Control Factors: Bromine Explosion At The Polar Arctic Sunrise

TL;DR

This paper investigates the Arctic bromine explosion, analyzing its atmospheric and biogeochemical impacts, and proposes a novel modeling approach supported by observational data to understand its role in climate regulation.

Contribution

It introduces a new empirical and modeling framework for understanding Arctic bromine chemistry and its influence on atmospheric ozone and climate control factors.

Findings

Quantified tropospheric BrO and Bry from Arctic bromine emissions.

Established a strong relationship between bromine chemistry and surface ozone levels.

Validated GEM model results with observational data.

Abstract

We attempt is to provide accumulated evidence and qualitative understanding of the associated atmospheric phenomena of the Arctic bromine explosion and their role in the functioning of the biotic Earth. We rationalize the empirical expression of the bromine influx into atmospheric boundary layer and calculate total amounts of the tropospheric BrO and Bry of the Arctic origin. Based on the quantities and partitioning of the reactive bromine species, we estimate the biogeochemical parametric constraint on the surface ozone field of the springtime NH. The constraint expresses strong relationship between atmosphere-climate control factors of the Earth's life and of external energy source. Physical atmosphere can be seen as a complex network of maximum complexity. Henceforth, we analyze the network context of the Arctic bromine pollution. We suggest that demonstrated attitudinal approach to the distributed surface flux would be successfully used in the innovative atmospheric modeling. The analysis is illustrated by GEM model results which stay in a good agreement with the observational data and support the original idea of the global NH effect of bromine chemistry.