Abstract
Abstract. The effects of future land use and land cover change on the chemical composition of the atmosphere and air quality are largely unknown. To investigate the potential effects associated with future changes in vegetation driven by atmospheric CO2 concentrations, climate, and anthropogenic land use over the 21st century, we performed a series of model experiments combining a general circulation model with a dynamic global vegetation model and an atmospheric chemical-transport model. Our results indicate that climate- and CO2-induced changes in vegetation composition and density between 2100 and 2000 could lead to decreases in summer afternoon surface ozone of up to 10 ppb over large areas of the northern mid-latitudes. This is largely driven by the substantial increases in ozone dry deposition associated with increases in vegetation density in a warmer climate with higher atmospheric CO2 abundance. Climate-driven vegetation changes over the period 2000–2100 lead to general increases in isoprene emissions, globally by 15% in 2050 and 36% in 2100. These increases in isoprene emissions result in decreases in surface ozone concentrations where the NOx levels are low, such as in remote tropical rainforests. However, over polluted regions, such as the northeastern United States, ozone concentrations are calculated to increase with higher isoprene emissions in the future. Increases in biogenic emissions also lead to higher concentrations of secondary organic aerosols, which increase globally by 10% in 2050 and 20% in 2100. Summertime surface concentrations of secondary organic aerosols are calculated to increase by up to 1 μg m−3 and double for large areas in Eurasia over the period of 2000–2100. When we use a scenario of future anthropogenic land use change, we find less increase in global isoprene emissions due to replacement of higher-emitting forests by lower-emitting cropland. The global atmospheric burden of secondary organic aerosols changes little by 2100 when we account for future land use change, but both secondary organic aerosols and ozone show large regional changes at the surface.
Highlights
Changes in land cover may have significant consequences for atmospheric composition and air quality
These changes in biogenic emissions indicate that the effects from climate-induced land cover change are comparable to those “direct” effects from climate change driven by changes in temperature and solar radiation
We investigated the potential effects on atmospheric chemistry and air quality from 2000–2100 changes in land use and land cover driven by climate change, increasing atmospheric CO2 abundance, and agricultural land use change
Summary
Changes in land cover may have significant consequences for atmospheric composition and air quality. Sanderson et al (2003) reported that neglecting potential future changes in land cover results in overestimates of 6 % in the projected increase in global isoprene emissions and of 5–30 ppb surface ozone levels due to climate change over the period 1990–2090. Ganzeveld and Lelieveld (2004) found significant effects on atmospheric chemistry from Amazonian deforestation, including strong decreases in ozone dry deposition and isoprene emissions. Ganzeveld et al (2010) calculated decreases in global isoprene emissions and increases in boundary layer ozone mixing ratios by up to 9 ppb in response to 2000–2050 changes in land use and land cover. Most of the previous studies discussed above, except for Sanderson et al (2003) and Ganzeveld et al (2010), focused on the effects of anthropogenic land use change on atmospheric chemistry and ignored potential future climate-driven changes in vegetation cover. We focus on the effects of land cover and land use change on tropospheric ozone and SOA, since they have important implications for climate and air quality
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