Your search keyword '"Bellouin, N."' showing total 10 results

1. Strong constraints on aerosol–cloud interactions from volcanic eruptions

Author

Malavelle, FF, Haywood, JM, Jones, A, Gettelman, A, Clarisse, L, Bauduin, S, Allan, RP, Karset, IHH, Kristjánsson, JE, Oreopoulos, L, Cho, N, Lee, D, Bellouin, N, Boucher, O, Grosvenor, DP, Carslaw, KS, Dhomse, S, Mann, GW, Schmidt, A, Coe, H, Hartley, ME, Dalvi, M, Hill, AA, Johnson, BT, Johnson, CE, Knight, JR, O’Connor, FM, Partridge, DG, Stier, P, Myhre, G, Platnick, S, Stephens, GL, Takahashi, H, and Thordarson, T

Abstract

Aerosols have a potentially large effect on climate, particularly through their interactions with clouds, but the magnitude of this effect is highly uncertain. Large volcanic eruptions produce sulfur dioxide, which in turn produces aerosols; these eruptions thus represent a natural experiment through which to quantify aerosol–cloud interactions. Here we show that the massive 2014–2015 fissure eruption in Holuhraun, Iceland, reduced the size of liquid cloud droplets—consistent with expectations—but had no discernible effect on other cloud properties. The reduction in droplet size led to cloud brightening and global-mean radiative forcing of around −0.2 watts per square metre for September to October 2014. Changes in cloud amount or cloud liquid water path, however, were undetectable, indicating that these indirect effects, and cloud systems in general, are well buffered against aerosol changes. This result will reduce uncertainties in future climate projections, because we are now able to reject results from climate models with an excessive liquid-water-path response.

Published

2017

2. Detection of solar dimming and brightening effects on Northern Hemisphere river flow

Author

Gedney, N., Huntingford, C., Weedon, G.P., Bellouin, N., Cox, P.M., Gedney, N., Huntingford, C., Weedon, G.P., Bellouin, N., and Cox, P.M.

Abstract

Anthropogenic aerosols in the atmosphere have the potential to affect regional-scale land hydrology through solar dimming1, 2. Increased aerosol loading may have reduced historical surface evaporation over some locations3, but the magnitude and extent of this effect is uncertain. Any reduction in evaporation due to historical solar dimming may have resulted in an increase in river flow. Here we formally detect and quantify the historical effect of changing aerosol concentrations, via solar radiation, on observed river flow over the heavily industrialized, northern extra-tropics. We use a state-of-the-art estimate of twentieth century surface meteorology4 as input data for a detailed land surface model5, and show that the simulations capture the observed strong inter-annual variability in runoff in response to climatic fluctuations. Using statistical techniques, we identify a detectable aerosol signal in the observed river flow both over the combined region, and over individual river basins in Europe and North America. We estimate that solar dimming due to rising aerosol concentrations in the atmosphere around 1980 led to an increase in river runoff by up to 25% in the most heavily polluted regions in Europe. We propose that, conversely, these regions may experience reduced freshwater availability in the future, as air quality improvements are set to lower aerosol loading and solar dimming.

Published

2014

3. Author Correction: Weak average liquid-cloud-water response to anthropogenic aerosols.

Author

Toll V, Christensen M, Quaas J, and Bellouin N

Abstract

An Amendment to this paper has been published and can be accessed via a link at the top of the paper.

Published

2020

4. Weak average liquid-cloud-water response to anthropogenic aerosols.

Author

Toll V, Christensen M, Quaas J, and Bellouin N

Subjects

Air Pollution analysis, Greenhouse Effect prevention & control, Greenhouse Effect statistics & numerical data, Rain, Uncertainty, Aerosols analysis, Aerosols chemistry, Climate Change statistics & numerical data, Human Activities, Models, Theoretical, Temperature, Water analysis, Water chemistry

Abstract

The cooling of the Earth's climate through the effects of anthropogenic aerosols on clouds offsets an unknown fraction of greenhouse gas warming. An increase in the amount of water inside liquid-phase clouds induced by aerosols, through the suppression of rain formation, has been postulated to lead to substantial cooling, which would imply that the Earth's surface temperature is highly sensitive to anthropogenic forcing. Here we provide direct observational evidence that, instead of a strong increase, aerosols cause a relatively weak average decrease in the amount of water in liquid-phase clouds compared with unpolluted clouds. Measurements of polluted clouds downwind of various anthropogenic sources-such as oil refineries, smelters, coal-fired power plants, cities, wildfires and ships-reveal that aerosol-induced cloud-water increases, caused by suppressed rain formation, and decreases, caused by enhanced evaporation of cloud water, partially cancel each other out. We estimate that the observed decrease in cloud water offsets 23% of the global climate-cooling effect caused by aerosol-induced increases in the concentration of cloud droplets. These findings invalidate the hypothesis that increases in cloud water cause a substantial climate cooling effect and translate into reduced uncertainty in projections of future climate.

Published

2019

5. Erratum: Strong constraints on aerosol-cloud interactions from volcanic eruptions.

Author

Malavelle FF, Haywood JM, Jones A, Gettelman A, Clarisse L, Bauduin S, Allan RP, Karset IHH, Kristjánsson JE, Oreopoulos L, Cho N, Lee D, Bellouin N, Boucher O, Grosvenor DP, Carslaw KS, Dhomse S, Mann GW, Schmidt A, Coe H, Hartley ME, Dalvi M, Hill AA, Johnson BT, Johnson CE, Knight JR, O'Connor FM, Partridge DG, Stier P, Myhre G, Platnick S, Stephens GL, Takahashi H, and Thordarson T

Abstract

This corrects the article DOI: 10.1038/nature22974.

Published

2017

6. Strong constraints on aerosol-cloud interactions from volcanic eruptions.

Author

Malavelle FF, Haywood JM, Jones A, Gettelman A, Clarisse L, Bauduin S, Allan RP, Karset IHH, Kristjánsson JE, Oreopoulos L, Cho N, Lee D, Bellouin N, Boucher O, Grosvenor DP, Carslaw KS, Dhomse S, Mann GW, Schmidt A, Coe H, Hartley ME, Dalvi M, Hill AA, Johnson BT, Johnson CE, Knight JR, O'Connor FM, Partridge DG, Stier P, Myhre G, Platnick S, Stephens GL, Takahashi H, and Thordarson T

Abstract

Aerosols have a potentially large effect on climate, particularly through their interactions with clouds, but the magnitude of this effect is highly uncertain. Large volcanic eruptions produce sulfur dioxide, which in turn produces aerosols; these eruptions thus represent a natural experiment through which to quantify aerosol-cloud interactions. Here we show that the massive 2014-2015 fissure eruption in Holuhraun, Iceland, reduced the size of liquid cloud droplets-consistent with expectations-but had no discernible effect on other cloud properties. The reduction in droplet size led to cloud brightening and global-mean radiative forcing of around -0.2 watts per square metre for September to October 2014. Changes in cloud amount or cloud liquid water path, however, were undetectable, indicating that these indirect effects, and cloud systems in general, are well buffered against aerosol changes. This result will reduce uncertainties in future climate projections, because we are now able to reject results from climate models with an excessive liquid-water-path response.

Published

2017

7. Climate change: Black carbon and atmospheric feedbacks.

Author

Booth B and Bellouin N

Subjects

Air Pollution legislation & jurisprudence, Air Pollution prevention & control, Air Pollution statistics & numerical data, Biofuels, Environmental Policy legislation & jurisprudence, Fossil Fuels, Global Warming prevention & control, Atmosphere chemistry, Feedback, Global Warming statistics & numerical data, Models, Theoretical, Soot analysis, Soot radiation effects, Sunlight

Published

2015

8. Aerosols implicated as a prime driver of twentieth-century North Atlantic climate variability.

Author

Booth BB, Dunstone NJ, Halloran PR, Andrews T, and Bellouin N

Subjects

Atlantic Ocean, Droughts, History, 19th Century, History, 20th Century, History, 21st Century, Human Activities, Radiation, Seawater, Temperature, Volcanic Eruptions, Water Movements, Aerosols, Climate, Global Warming statistics & numerical data

Abstract

Systematic climate shifts have been linked to multidecadal variability in observed sea surface temperatures in the North Atlantic Ocean. These links are extensive, influencing a range of climate processes such as hurricane activity and African Sahel and Amazonian droughts. The variability is distinct from historical global-mean temperature changes and is commonly attributed to natural ocean oscillations. A number of studies have provided evidence that aerosols can influence long-term changes in sea surface temperatures, but climate models have so far failed to reproduce these interactions and the role of aerosols in decadal variability remains unclear. Here we use a state-of-the-art Earth system climate model to show that aerosol emissions and periods of volcanic activity explain 76 per cent of the simulated multidecadal variance in detrended 1860-2005 North Atlantic sea surface temperatures. After 1950, simulated variability is within observational estimates; our estimates for 1910-1940 capture twice the warming of previous generation models but do not explain the entire observed trend. Other processes, such as ocean circulation, may also have contributed to variability in the early twentieth century. Mechanistically, we find that inclusion of aerosol-cloud microphysical effects, which were included in few previous multimodel ensembles, dominates the magnitude (80 per cent) and the spatial pattern of the total surface aerosol forcing in the North Atlantic. Our findings suggest that anthropogenic aerosol emissions influenced a range of societally important historical climate events such as peaks in hurricane activity and Sahel drought. Decadal-scale model predictions of regional Atlantic climate will probably be improved by incorporating aerosol-cloud microphysical interactions and estimates of future concentrations of aerosols, emissions of which are directly addressable by policy actions.

Published

2012

9. Impact of changes in diffuse radiation on the global land carbon sink.

Author

Mercado LM, Bellouin N, Sitch S, Boucher O, Huntingford C, Wild M, and Cox PM

Subjects

Aerosols analysis, Aerosols chemistry, Carbon Dioxide analysis, Greenhouse Effect, History, 20th Century, History, 21st Century, Plants metabolism, Sulfates metabolism, Volcanic Eruptions, Atmosphere chemistry, Carbon metabolism, Darkness, Ecosystem, Photosynthesis radiation effects, Plants radiation effects, Sunlight

Abstract

Plant photosynthesis tends to increase with irradiance. However, recent theoretical and observational studies have demonstrated that photosynthesis is also more efficient under diffuse light conditions. Changes in cloud cover or atmospheric aerosol loadings, arising from either volcanic or anthropogenic emissions, alter both the total photosynthetically active radiation reaching the surface and the fraction of this radiation that is diffuse, with uncertain overall effects on global plant productivity and the land carbon sink. Here we estimate the impact of variations in diffuse fraction on the land carbon sink using a global model modified to account for the effects of variations in both direct and diffuse radiation on canopy photosynthesis. We estimate that variations in diffuse fraction, associated largely with the 'global dimming' period, enhanced the land carbon sink by approximately one-quarter between 1960 and 1999. However, under a climate mitigation scenario for the twenty-first century in which sulphate aerosols decline before atmospheric CO(2) is stabilized, this 'diffuse-radiation' fertilization effect declines rapidly to near zero by the end of the twenty-first century.

Published

2009

10. Global estimate of aerosol direct radiative forcing from satellite measurements.

Author

Bellouin N, Boucher O, Haywood J, and Reddy MS

Subjects

Aerosols chemistry, Algorithms, Biomass, Geography, Greenhouse Effect, Monte Carlo Method, Oceans and Seas, Probability, Satellite Communications, Thermodynamics, Wind, Aerosols analysis, Aerosols radiation effects, Atmosphere chemistry, Radiation

Abstract

Atmospheric aerosols cause scattering and absorption of incoming solar radiation. Additional anthropogenic aerosols released into the atmosphere thus exert a direct radiative forcing on the climate system. The degree of present-day aerosol forcing is estimated from global models that incorporate a representation of the aerosol cycles. Although the models are compared and validated against observations, these estimates remain uncertain. Previous satellite measurements of the direct effect of aerosols contained limited information about aerosol type, and were confined to oceans only. Here we use state-of-the-art satellite-based measurements of aerosols and surface wind speed to estimate the clear-sky direct radiative forcing for 2002, incorporating measurements over land and ocean. We use a Monte Carlo approach to account for uncertainties in aerosol measurements and in the algorithm used. Probability density functions obtained for the direct radiative forcing at the top of the atmosphere give a clear-sky, global, annual average of -1.9 W m(-2) with standard deviation, +/- 0.3 W m(-2). These results suggest that present-day direct radiative forcing is stronger than present model estimates, implying future atmospheric warming greater than is presently predicted, as aerosol emissions continue to decline.

Published

2005