The potential effects of climate change on air quality  across the conterminous US at 2030 under three  Representative Concentration Pathways

Nolte, Christopher G.; Spero, Tanya L.; Bowden, Jared H.; Mallard, Megan S.; Dolwick, Pat

doi:10.5194/acp-18-15471-2018

Cited by 41 publications

(39 citation statements)

References 83 publications

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“…Hence, compensating effects from these processes and model differences in parameterizations of BVOC and lightning NO x emissions, and STE lead to low sensitivity of surface ozone to climate change and lack of model agreement for the sign of changes under global warming. The above mentioned heterogeneity in model results is also found in previous regional studies focusing on North America (Gonzalez-Abraham et al 2015, Val Martin et al 2015, Schnell et al 2016, He et al 2018, Nolte et al 2018, Rieder et al 2018 or Europe (Katragkou et al 2011, Colette et al 2015, Lacressonnière et al 2016, Schnell et al 2016, Fortems-Cheiney et al 2017. For European land areas, previous studies have estimated a summertime average ozone climate penalty as a function of the average European surface temperature anomaly of +0.17 ppbv • C −1 (Colette et al 2015), which is consistent with the estimated range of 0 to +0.2 ppbv • C −1 inferred by the multi-model mean of CMIP6 models over parts of Europe.…”

Section: Discussionsupporting

confidence: 75%

“…The above-mentioned IPCC AR5 assessment is also supported by several recent studies based on model projections either with global or regional models. The majority of the regional studies are focusing on North America (Gonzalez-Abraham et al 2015, Val Martin et al 2015, Schnell et al 2016, He et al 2018, Nolte et al 2018, Rieder et al 2018, Gao et al 2020 or Europe (Colette et al 2015, Lacressonnière et al 2016, Schnell et al 2016, Fortems-Cheiney et al 2017, but there are also a few studies focused on East Asia (Lee et al 2015, Schnell et al 2016 and India (Pommier et al 2018). Over polluted regions of the world, such as in North America, Europe, and East Asia, model studies project a general increase of surface ozone levels in a future warmer climate, particularly during summertime as has been recently reviewed (Fu and Tian 2019).…”

Section: Introductionmentioning

confidence: 99%

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Climate change penalty and benefit on surface ozone: a global perspective based on CMIP6 earth system models

Zanis

Akritidis

Turnock

et al. 2022

Environ. Res. Lett.

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This work presents an analysis of the effect of climate change on surface ozone discussing the related penalties and benefits around the globe from the global modeling perspective based on simulations with five CMIP6 (Coupled Model Intercomparison Project Phase 6) Earth System Models. As part of AerChemMIP (Aerosol Chemistry Model Intercomparison Project) all models conducted simulation experiments considering future climate (ssp370SST) and present-day climate (ssp370pdSST) under the same future emissions trajectory (SSP3-7.0). A multi-model global average climate change benefit on surface ozone of -0.96±0.07 ppbv oC-1 is calculated which is mainly linked to the dominating role of enhanced ozone destruction with higher water vapour abudances under a warmer climate. Over regions remote from pollution sources, there is a robust decline in mean surface ozone concentration on an annual basis as well as for boreal winter and summer varying spatially from -0.2 to -2 ppbv oC-1, with strongest decline over tropical oceanic regions. The implication is that over regions remote from pollution sources (except over the Arctic) there is a consistent climate change benefit for baseline ozone due to global warming. However, ozone increases over regions close to anthropogenic pollution sources or close to enhanced natural Biogenic Volatile Organic Compounds (BVOC) emission sources with a rate ranging regionally from 0.2 to 2 ppbv oC-1, implying a regional surface ozone penalty due to global warming. Overall, the future climate change enhances the efficiency of precursor emissions to generate surface ozone in polluted regions and thus the magnitude of this effect depends on the regional emission changes considered in this study within the SSP3_7.0 scenario. The comparison of the climate change impact effect on surface ozone versus the combined effect of climate and emission changes indicates the dominant role of precursor emission changes in projecting surface ozone concentrations under future climate change scenarios.

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Section: Discussionsupporting

confidence: 75%

Section: Introductionmentioning

confidence: 99%

Climate change penalty and benefit on surface ozone: a global perspective based on CMIP6 earth system models

Zanis

Akritidis

Turnock

et al. 2022

Environ. Res. Lett.

View full text Add to dashboard Cite

show abstract

“…Regarding time-varying meteorology, in our study running GEOS-Chem with future meteorology was not possible since the model was not configured to use outputs from global climate models. Recent evidence suggests, however, that our use of present-day meteorological fields when simulating wildfire emissions effects on PM 2.5 concentrations likely leads to underestimated impacts on wildfire-related PM 2.5 due to a shorter lifetime of PM 2.5 than might be expected in the future in areas projected to experience reductions in precipitation [ 29 , 43 , 44 ]. The net effects of climate change on meteorology remain important for estimating PM 2.5 concentrations.…”

Section: Discussionmentioning

confidence: 99%

Estimating PM2.5-related premature mortality and morbidity associated with future wildfire emissions in the western US

Neumann¹,

Amend²,

Anenberg

et al. 2021

Environ. Res. Lett.

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Wildfire activity in the western United States (US) has been increasing, a trend that has been correlated with changing patterns of temperature and precipitation associated with climate change. Health effects associated with exposure to wildfire smoke and fine particulate matter (PM 2.5 ) include short- and long-term premature mortality, hospital admissions, emergency department visits, and other respiratory and cardiovascular incidents. We estimate PM 2.5 exposure and health impacts for the entire continental US from current and future western US wildfire activity projected for a range of future climate scenarios through the 21st century. We use a simulation approach to estimate wildfire activity, area burned, fine particulate emissions, air quality concentrations, health effects, and economic valuation of health effects, using established and novel methodologies. We find that climatic factors increase wildfire pollutant emissions by an average of 0.40% per year over the 2006–2100 period under Representative Concentration Pathway (RCP) 4.5 (lower emissions scenarios) and 0.71% per year for RCP8.5. As a consequence, spatially weighted wildfire PM 2.5 concentrations more than double for some climate model projections by the end of the 21st century. PM 2.5 exposure changes, combined with population projections, result in a wildfire PM2.5-related premature mortality excess burden in the 2090 RCP8.5 scenario that is roughly 3.5 times larger than in the baseline period. The combined effect of increased wildfire activity, population growth, and increase in the valuation of avoided risk of premature mortality over time results in a large increase in total economic impact of wildfire-related PM 2.5 mortality and morbidity in the continental US, from roughly $7 billion per year in the baseline period to roughly $36 billion per year in 2090 for RCP4.5, and $43 billion per year in RCP8.5. The climate effect alone accounts for a roughly 60% increase in wildfire PM2.5-related premature mortality in the RCP8.5 scenario, relative to baseline conditions.

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“…[23] In addition, climate change is expected to exacerbate further human health impacts by increasing weather conditions that enhance air pollution exposure, mainly to PM 2.5 and ozone. [24,25] To break the cycle of air pollution and climate change, air pollution needs to be restricted more drastically. In this regard, air filters provide a suitable method for air purification.…”

Section: Air Pollutants and Their Impactmentioning

confidence: 99%

Review on Polymeric, Inorganic, and Composite Materials for Air Filters: From Processing to Properties

Henning

Abdullayev

Vakifahmetoğlu

et al. 2021

Adv Energy and Sustain Res

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Particulate and gaseous air pollutants pose a threat to human health and contribute to climate change. By today, air filters, stationary and portable, are markedly improved and can often provide innocuous air pollution levels. After introducing the classification and standards on air filters, the influence of the processing route and its parameters on the resulting air filter properties and consequently its performance are discussed. Numerous tools are presented to adjust structural properties such as fiber or pore diameter, specific surface area, surface charge, hydrophilicity, or photocatalytic activity to achieve the desired performance in terms of high filtration efficiencies, sufficient mechanical stability, regeneration eligibility, antimicrobial and optical properties. In particular, inorganic and composite materials as well as nonfibrous structures are covered, which are currently holding an outsider position in an air filter community dominated by polymeric materials and fibrous structures.

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The potential effects of climate change on air quality across the conterminous US at 2030 under three Representative Concentration Pathways

Cited by 41 publications

References 83 publications

Climate change penalty and benefit on surface ozone: a global perspective based on CMIP6 earth system models

Climate change penalty and benefit on surface ozone: a global perspective based on CMIP6 earth system models

Estimating PM2.5-related premature mortality and morbidity associated with future wildfire emissions in the western US

Review on Polymeric, Inorganic, and Composite Materials for Air Filters: From Processing to Properties

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