Importance of tropospheric volcanic aerosol for indirect radiative forcing of climate

A Schmidt,P M Forster,K S Carslaw,A Rap,D V Spracklen,M Wilson,G W Mann,K J Pringle

doi:10.5194/acp-12-7321-2012

A Schmidt, P M Forster + Show 6 more

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https://doi.org/10.5194/acp-12-7321-2012

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Abstract

Abstract. Observations and models have shown that continuously degassing volcanoes have a potentially large effect on the natural background aerosol loading and the radiative state of the atmosphere. We use a global aerosol microphysics model to quantify the impact of these volcanic emissions on the cloud albedo radiative forcing under pre-industrial (PI) and present-day (PD) conditions. We find that volcanic degassing increases global annual mean cloud droplet number concentrations by 40% under PI conditions, but by only 10% under PD conditions. Consequently, volcanic degassing causes a global annual mean cloud albedo effect of −1.06 W m−2 in the PI era but only −0.56 W m−2 in the PD era. This non-equal effect is explained partly by the lower background aerosol concentrations in the PI era, but also because more aerosol particles are produced per unit of volcanic sulphur emission in the PI atmosphere. The higher sensitivity of the PI atmosphere to volcanic emissions has an important consequence for the anthropogenic cloud radiative forcing because the large uncertainty in volcanic emissions translates into an uncertainty in the PI baseline cloud radiative state. Assuming a −50/+100% uncertainty range in the volcanic sulphur flux, we estimate the annual mean anthropogenic cloud albedo forcing to lie between −1.16 W m−2 and −0.86 W m−2. Therefore, the volcanically induced uncertainty in the PI baseline cloud radiative state substantially adds to the already large uncertainty in the magnitude of the indirect radiative forcing of climate.

Highlights

The impacts of volcanic eruptions on Earth’s radiation budget, the environment and human health have been well documented (e.g., Robock, 2000; Baxter, 2000; Delmelle et al, 2002; Schmidt et al, 2011)
The relative changes in cloud condensation nuclei (CCN) concentrations are non-linear: the greater the change in volcanic sulphur flux, the less effectively these emissions contribute to global CCN
To help understand what drives this non-linear CCN sensitivity to volcanic SO2 emissions, we analyse diagnostics for the sulphur fluxes through the chemical and microphysical processes (Table 2)

Summary

Introduction

The impacts of volcanic eruptions on Earth’s radiation budget, the environment and human health have been well documented (e.g., Robock, 2000; Baxter, 2000; Delmelle et al, 2002; Schmidt et al, 2011). The atmospheric and climatic effects of volcanic aerosol released into the troposphere by continuously degassing and sporadically erupting volcanoes (hereafter “volcanic degassing”) have only gradually become of greater interest to the geosciences community (Chin and Jacob, 1996; Graf et al, 1997, 1998; Stevenson et al, 2003a; Mather et al, 2003b; Textor et al, 2004; Gasso, 2008; Yuan et al, 2011; Oppenheimer et al, 2011) In their recent review of sulphur degassing from volcanoes, Oppenheimer et al (2011) concluded that “changes in time and space in this “background” emission could represent an important forcing factor that has yet to be characterized.”. The inventory is widely used in atmospheric modelling studies, such as the AEROCOM international model intercomparison

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