chemical equator, in Earth’s atmosphere, a boundary region of air extending from Earth’s surface to an altitude of about 8 km (5 miles) that separates heavily polluted air in the Northern Hemisphere from less-polluted air in the Southern Hemisphere. Although the chemical equator appears to follow the path of the intertropical convergence zone (ITCZ), the belt of converging trade winds and rising air (which is often characterized by clouds and precipitation) that encircles Earth near its geographic Equator, the chemical equator has been shown to diverge from the ITCZ over the western Pacific Ocean.
The ITCZ had long been acknowledged as the sole meteorological barrier that inhibits the movement and mixing of air between Earth’s Northern and Southern Hemispheres; however, the discovery in 2006 of a sharp chemical gradient away from the path of the ITCZ indicated that this is not always the case. This first evidence of a chemical equator was published by a group of chemistry researchers from the University of York, in the United Kingdom, in 2008, after they noticed a 50-km (31-mile) wide region characterized by a rapid change in the concentration of carbon monoxide (CO), an industrial pollutant, over part of the western Pacific from data collected in 2006. The position of this gradient, which during January and February 2006 occurred during cloud-free conditions over the western Pacific Ocean between northern Australia and Indonesia, did not correspond to the position of the ITCZ. During this period, the ITCZ was located further south over central Australia. The development of this CO gradient was explained by the interplay of the seasonal monsoon and westerly winds, which had the effect of temporarily pushing dry Southern Hemisphere air northward away from the ITCZ.
One of the first global maps that attempted to describe the position of Earth’s chemical equator was created in 2022 by an international team of researchers from the Institute of Environmental Physics and the Alfred Wegener Institute, both in Germany. They examined the simulated movement of methane (CH4) and sulfur hexafluoride (SF6), which were selected because they have longer residence times in the atmosphere compared with CO, using a complex global atmospheric model (see also scientific modeling). The model’s results were compared with mapped concentrations of CH4 and SF6 in the atmosphere between 2015 and 2019. The results of the study showed that while the chemical equator largely coincides with the ITCZ, complex wind-flow patterns over certain areas, such as the western Pacific Ocean, cause these boundaries to diverge from one another at certain times. They also discovered that the width of the chemical equator varies seasonally.