Direct and Semi‐Direct Aerosol Effects: a Modeled Study for Biomass Burning Aerosol Radiative Forcing in the Amazon Region

The CMIP6 Shared Socioeconomic Pathway (SSP) scenarios include projections of future changes in anthropogenic biomass-burning.&#160; Globally, they assume a decrease in total fire emissions over the next century under all scenarios.&#160; However, fire regimes and emissions are expected to additionally change with future climate, and the methodology used to project fire emissions in the SSP scenarios is opaque.We aim to provide a more traceable estimate of future fire emissions under CMIP6 scenarios and evaluate the impacts for aerosol radiative forcing. &#160;We utilise interactive wildfire emissions from four independent land-surface models (CLM5, JSBACH3.2, LPJ-GUESS, and ISBA-CTRIP) used within CMIP6 ESMs, and two different machine-learning methods (a random forest, and a generalised additive model) trained on historical data, to predict year 2100 biomass-burning aerosol emissions consistent with the CMIP6-modelled climate for three different scenarios: SSP126, SSP370, and SSP585.&#160; This multi-method approach provides future fire emissions integrating information from observations, projections of climate, socioeconomic parameters and changes in vegetation distribution and fuel loads.Our analysis shows a robust increase in fire emissions for large areas of the extra-tropics until the end of this century for all methods.&#160; Although this pattern was present to an extent in the original SSP projections, both the interactive fire models and machine-learning methods predict substantially higher increases in extra-tropical emissions in 2100 than the corresponding SSP datasets.&#160; Within the tropics the signal is mixed. Increases in emissions are largely driven by the temperature changes, while in some tropical areas reductions in fire emissions are driven by human factors and changes in precipitation, with the largest reductions in Africa. The machine-learning methods show a stronger reduction in the tropics than the interactive fire models, however overall there is strong agreement between both the models and the machine-learning methods.We then use additional nudged atmospheric simulations with two state-of-the-art composition-climate models, UKESM1 and CESM2, to diagnose the impact of these updated fire emissions on aerosol burden and radiative forcing, compared with the original SSP prescribed emissions.&#160; We provide estimates of future fire radiative forcing, compared to modern-day, under these CMIP6 scenarios which span both the severity of climate change in 2100, and the rate of reduction of other aerosol species.

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Modeling the radiative effects of biomass burning aerosols on carbon fluxes in the Amazon region

Atmospheric Chemistry and Physics ◽

10.5194/acp-17-14785-2017 ◽

2017 ◽

Vol 17 (23) ◽

pp. 14785-14810 ◽

Cited By ~ 10

Author(s):

Demerval S. Moreira ◽

Karla M. Longo ◽

Saulo R. Freitas ◽

Marcia A. Yamasoe ◽

Lina M. Mercado ◽

...

Keyword(s):

Solar Radiation ◽

South America ◽

Biomass Burning ◽

Radiation Effect ◽

Diffuse Radiation ◽

Amazon Region ◽

Co2 Fluxes ◽

Biomass Burning Aerosol ◽

Aerosol Effects ◽

The Impact

Abstract. Every year, a dense smoke haze covers a large portion of South America originating from fires in the Amazon Basin and central parts of Brazil during the dry biomass burning season between August and October. Over a large portion of South America, the average aerosol optical depth at 550 nm exceeds 1.0 during the fire season, while the background value during the rainy season is below 0.2. Biomass burning aerosol particles increase scattering and absorption of the incident solar radiation. The regional-scale aerosol layer reduces the amount of solar energy reaching the surface, cools the near-surface air, and increases the diffuse radiation fraction over a large disturbed area of the Amazon rainforest. These factors affect the energy and CO2 fluxes at the surface. In this work, we applied a fully integrated atmospheric model to assess the impact of biomass burning aerosols in CO2 fluxes in the Amazon region during 2010. We address the effects of the attenuation of global solar radiation and the enhancement of the diffuse solar radiation flux inside the vegetation canopy. Our results indicate that biomass burning aerosols led to increases of about 27 % in the gross primary productivity of Amazonia and 10 % in plant respiration as well as a decline in soil respiration of 3 %. Consequently, in our model Amazonia became a net carbon sink; net ecosystem exchange during September 2010 dropped from +101 to −104 TgC when the aerosol effects are considered, mainly due to the aerosol diffuse radiation effect. For the forest biome, our results point to a dominance of the diffuse radiation effect on CO2 fluxes, reaching a balance of 50–50 % between the diffuse and direct aerosol effects for high aerosol loads. For C3 grasses and savanna (cerrado), as expected, the contribution of the diffuse radiation effect is much lower, tending to zero with the increase in aerosol load. Taking all biomes together, our model shows the Amazon during the dry season, in the presence of high biomass burning aerosol loads, changing from being a source to being a sink of CO2 to the atmosphere.

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On the (in)accuracy of the spherical particle approximation in mineral aerosol radiative forcing simulations

Conference on Electromagnetic and Light Scattering ◽

10.1615/ichmt.2007.confelectromagligscat.210 ◽

2007 ◽

Author(s):

Michael Kahnert ◽

Timo Nousiainen ◽

Petri Raisanen

Keyword(s):

Spherical Particle ◽

Radiative Forcing ◽

Aerosol Radiative Forcing ◽

Particle Approximation ◽

Aerosol Radiative

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The Impact of Changes in Cloud Water pH on Aerosol Radiative Forcing

Geophysical Research Letters ◽

10.1029/2019gl082067 ◽

2019 ◽

Vol 46 (7) ◽

pp. 4039-4048 ◽

Cited By ~ 7

Author(s):

S. T. Turnock ◽

G. W. Mann ◽

M. T. Woodhouse ◽

M. Dalvi ◽

F. M. O'Connor ◽

...

Keyword(s):

Radiative Forcing ◽

Cloud Water ◽

Aerosol Radiative Forcing ◽

Water Ph ◽

The Impact ◽

Aerosol Radiative

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Estimates of direct radiative forcing due to aerosols from the MERRA-2 reanalysis over the Amazon region

10.5194/acp-2018-355 ◽

2018 ◽

Cited By ~ 1

Author(s):

Brunna Penna ◽

Dirceu Herdies ◽

Simone Costa

Keyword(s):

Radiative Forcing ◽

Reanalysis Data ◽

Amazon Region ◽

Reference State ◽

Aerosol Radiative Forcing ◽

Aerosol Loading ◽

Direct Radiative Forcing ◽

Direct Forcing ◽

The Difference ◽

Natural Aerosols

Abstract. Sixteen years of analysis of clear-sky direct aerosol radiative forcing is presented for the Amazon region, with calculations of AERONET network, MODIS sensor and MERRA-2 reanalysis data. The results showed that MERRA-2 reanalysis is an excellent tool for calculating and providing the spatial distribution of aerosol direct radiative forcing. In addition, the difference between considering the reference state of the atmosphere without aerosol loading and with natural aerosol to obtain the aerosol direct radiative forcing is discussed. During the dry season, the monthly average direct forcing at the top of atmosphere varied from −9.60 to −4.20 Wm−2, and at the surface, it varied from −29.81 to −9.24 Wm−2, according to MERRA-2 reanalysis data and the reference state of atmosphere without aerosol loading. Already with the state of reference being the natural aerosols, the average direct forcing at the top of atmosphere varied from −5.15 to −1.18 Wm−2, and at the surface, it varied from −21.28 to −5.25 Wm−2; this difference was associated with the absorption of aerosols.

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