Atmospheric sulfur hexafluoride: Sources, sinks and greenhouse warming

Abstract

Model calculations using estimated reaction rates of sulfur hexafluoride (SF₆) with OH and O(¹D) indicate that the atmospheric lifetime due to these processes may be very long (25,000 years). An upper limit for the UV cross section would suggest a photolysis lifetime much longer than 1000 years. The possibility of other removal mechanisms are discussed. The estimated lifetimes are consistent with other estimated values based on recent laboratory measurements. There appears to be no known natural source of SF₆. An estimate of the current production rate of SF₆ is about 5 kt/yr. Based on historical emission rates, we calculated a present‐day atmospheric concentrations for SF₆ of about 2.5 parts per trillion by volume (pptv) and compared the results with available atmospheric measurements. It is difficult to estimate the atmospheric lifetime of SF₆ based on mass balance of the emission rate and observed abundance. There are large uncertainties concerning what portion of the SF₆ is released to the atmosphere. Even if the emission rate were precisely known, it would be difficult to distinguish among lifetimes longer than 100 years since the current abundance of SF₆ is due to emission in the past three decades. More information on the measured trends over the past decade and observed vertical and latitudinal distributions of SF₆ in the lower stratosphere will help to narrow the uncertainty in the lifetime. Based on laboratory‐measured IR absorption cross section for SF₆, we showed that SF₆ is about 3 times more effective as a greenhouse gas compared to CFC 11 on a per molecule basis. However, its effect on atmospheric warming will be minimal because of its very small concentration. We estimated the future concentration of SF₆ at 2010 to be 8 and 10 pptv based on two projected emission scenarios. The corresponding equilibrium warming of 0.0035°C and 0.0043°C is to be compared with the estimated warming due to CO₂ increase of about 0.8°C in the same period.