Your search keyword '"Hossaini, R"' showing total 4 results

1. Natural halogens buffer tropospheric ozone in a changing climate

Author

European Commission, National Science Foundation (US), Department of Energy (US), National Center for Atmospheric Research (US), Iglesias-Suarez, Fernando, Badía, Alba, Fernández, Rafael P., Cuevas, Carlos A., Kinnison, Douglas E., Tilmes, Simone, Lamarque, Jean-François, Long, M .C., Hossaini, R., Saiz-Lopez, A., European Commission, National Science Foundation (US), Department of Energy (US), National Center for Atmospheric Research (US), Iglesias-Suarez, Fernando, Badía, Alba, Fernández, Rafael P., Cuevas, Carlos A., Kinnison, Douglas E., Tilmes, Simone, Lamarque, Jean-François, Long, M .C., Hossaini, R., and Saiz-Lopez, A.

Abstract

Reactive atmospheric halogens destroy tropospheric ozone (O3), an air pollutant and greenhouse gas. The primary source of natural halogens is emissions from marine phytoplankton and algae, as well as abiotic sources from ocean and tropospheric chemistry, but how their fluxes will change under climate warming, and the resulting impacts on O3, are not well known. Here, we use an Earth system model to estimate that natural halogens deplete approximately 13% of tropospheric O3 in the present-day climate. Despite increased levels of natural halogens through the twenty-first century, this fraction remains stable due to compensation from hemispheric, regional and vertical heterogeneity in tropospheric O3 loss. Notably, this halogen-driven O3 buffering is projected to be greatest over polluted and populated regions, due mainly to iodine chemistry, with important implications for air quality.

Published

2020

2. Delay in recovery of the Antarctic ozone hole from unexpected CFC-11 emissions.

Author

Dhomse, S. S., Feng, W., Montzka, S. A., Hossaini, R., Keeble, J., Pyle, J. A., Daniel, J. S., and Chipperfield, M. P.

Subjects

EMISSIONS (Air pollution), OZONE layer depletion, TRICHLOROFLUOROMETHANE, CHLOROFLUOROCARBONS, VIENNA Convention for the Protection of the Ozone Layer (1985). Protocols, etc., 1987 Sept. 15

Abstract

The Antarctic ozone hole is decreasing in size but this recovery will be affected by atmospheric variability and any unexpected changes in chlorinated source gas emissions. Here, using model simulations, we show that the ozone hole will largely cease to occur by 2065 given compliance with the Montreal Protocol. If the unusual meteorology of 2002 is repeated, an ozone-hole-free-year could occur as soon as the early 2020s by some metrics. The recently discovered increase in CFC-11 emissions of ~ 13 Gg yr−1 may delay recovery. So far the impact on ozone is small, but if these emissions indicate production for foam use much more CFC-11 may be leaked in the future. Assuming such production over 10 years, disappearance of the ozone hole will be delayed by a few years, although there are significant uncertainties. Continued, substantial future CFC-11 emissions of 67 Gg yr−1 would delay Antarctic ozone recovery by well over a decade. The Antarctic ozone hole is decreasing in size due to policies implemented following the Montreal Protocol. Here, model simulations show that if recently discovered increase in unreported CFC-11 emissions continue, they could delay the recovery of the ozone hole by well over a decade. [ABSTRACT FROM AUTHOR]

Published

2019

3. Efficiency of short-lived halogens at influencing climate through depletion of stratospheric ozone.

Author

Hossaini, R., Chipperfield, M. P., Montzka, S. A., Rap, A., Dhomse, S., and Feng, W.

Subjects

*OZONE layer depletion, *HALOGENS, *GREENHOUSE gas mitigation, *STRATOSPHERIC aerosols, *HALOCARBONS

Abstract

Halogens released from long-lived anthropogenic substances, such as chlorofluorocarbons, are the principal cause of recent depletion of stratospheric ozone, a greenhouse gas. Recent observations show that very short-lived substances, with lifetimes generally under six months, are also an important source of stratospheric halogens. Short-lived bromine substances are produced naturally by seaweed and phytoplankton, whereas short-lived chlorine substances are primarily anthropogenic. Here we used a chemical transport model to quantify the depletion of ozone in the lower stratosphere from short-lived halogen substances, and a radiative transfer model to quantify the radiative effects of that ozone depletion. According to our simulations, ozone loss from short-lived substances had a radiative effect nearly half that from long-lived halocarbons in 2011 and, since pre-industrial times, has contributed a total of about −0.02 W m−2 to global radiative forcing. We find natural short-lived bromine substances exert a 3.6 times larger ozone radiative effect than long-lived halocarbons, normalized by halogen content, and show atmospheric levels of dichloromethane, a short-lived chlorine substance not controlled by the Montreal Protocol, are rapidly increasing. We conclude that potential further significant increases in the atmospheric abundance of short-lived halogen substances, through changing natural processes or continued anthropogenic emissions, could be important for future climate. [ABSTRACT FROM AUTHOR]

Published

2015

4. Recent Northern Hemisphere stratospheric HCl increase due to atmospheric circulation changes.

Author

Mahieu, E., Franco, B., Servais, C., Morino, I., Nakajima, H., Murata, I., Smale, D., Walker, K. A., Chipperfield, M. P., Dhomse, S. S., Feng, W., Hossaini, R., Notholt, J., Palm, M., Reddmann, T., Blumenstock, T., Hase, F., Schneider, M., Anderson, J., and III, J. M. Russell

Subjects

STRATOSPHERE, ATMOSPHERIC circulation, OZONE layer depletion, CHLORINE & the environment

Abstract

The abundance of chlorine in the Earth's atmosphere increased considerably during the 1970s to 1990s, following large emissions of anthropogenic long-lived chlorine-containing source gases, notably the chlorofluorocarbons. The chemical inertness of chlorofluorocarbons allows their transport and mixing throughout the troposphere on a global scale, before they reach the stratosphere where they release chlorine atoms that cause ozone depletion. The large ozone loss over Antarctica was the key observation that stimulated the definition and signing in 1987 of the Montreal Protocol, an international treaty establishing a schedule to reduce the production of the major chlorine- and bromine-containing halocarbons. Owing to its implementation, the near-surface total chlorine concentration showed a maximum in 1993, followed by a decrease of half a per cent to one per cent per year, in line with expectations. Remote-sensing data have revealed a peak in stratospheric chlorine after 1996, then a decrease of close to one per cent per year, in agreement with the surface observations of the chlorine source gases and model calculations. Here we present ground-based and satellite data that show a recent and significant increase, at the 2σ level, in hydrogen chloride (HCl), the main stratospheric chlorine reservoir, starting around 2007 in the lower stratosphere of the Northern Hemisphere, in contrast with the ongoing monotonic decrease of near-surface source gases. Using model simulations, we attribute this trend anomaly to a slowdown in the Northern Hemisphere atmospheric circulation, occurring over several consecutive years, transporting more aged air to the lower stratosphere, and characterized by a larger relative conversion of source gases to HCl. This short-term dynamical variability will also affect other stratospheric tracers and needs to be accounted for when studying the evolution of the stratospheric ozone layer. [ABSTRACT FROM AUTHOR]

Published

2014