Uncertainties in isoprene photochemistry and emissions: implications for the oxidative capacity of past and present atmospheres and for climate forcing agents

Achakulwisut, P.; Mickley, Loretta J.; Murray, Lee T.; Tai, Amos P. K.; Kaplan, Jed O.; Alexander, Becky

doi:10.5194/acp-15-7977-2015

Cited by 12 publications

(14 citation statements)

References 107 publications

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“…Background ozone, however, may increase due to increasing methane ( West et al, 2012 ). A major challenge in quantifying the future trends in surface air quality is our lack of knowledge in temperature-dependent isoprene emissions and photochemistry ( Achakulwisut et al, 2015 ).…”

Section: Chemistry–climate Interactionsmentioning

confidence: 99%

Southeast Atmosphere Studies: learning from model-observation syntheses

et al. 2018

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Concentrations of atmospheric trace species in the United States have changed dramatically over the past several decades in response to pollution control strategies, shifts in domestic energy policy and economics, and economic development (and resulting emission changes) elsewhere in the world. Reliable projections of the future atmosphere require models to not only accurately describe current atmospheric concentrations, but to do so by representing chemical, physical and biological processes with conceptual and quantitative fidelity. Only through incorporation of the processes controlling emissions and chemical mechanisms that represent the key transformations among reactive molecules can models reliably project the impacts of future policy, energy and climate scenarios. Efforts to properly identify and implement the fundamental and controlling mechanisms in atmospheric models benefit from intensive observation periods, during which collocated measurements of diverse, speciated chemicals in both the gas and condensed phases are obtained. The Southeast Atmosphere Studies (SAS, including SENEX, SOAS, NOMADSS and SEAC4RS) conducted during the summer of 2013 provided an unprecedented opportunity for the atmospheric modeling community to come together to evaluate, diagnose and improve the representation of fundamental climate and air quality processes in models of varying temporal and spatial scales.This paper is aimed at discussing progress in evaluating, diagnosing and improving air quality and climate modeling using comparisons to SAS observations as a guide to thinking about improvements to mechanisms and parameterizations in models. The effort focused primarily on model representation of fundamental atmospheric processes that are essential to the formation of ozone, secondary organic aerosol (SOA) and other trace species in the troposphere, with the ultimate goal of understanding the radiative impacts of these species in the southeast and elsewhere. Here we address questions surrounding four key themes: gas-phase chemistry, aerosol chemistry, regional climate and chemistry interactions, and natural and anthropogenic emissions. We expect this review to serve as a guidance for future modeling efforts.

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Section: Chemistry–climate Interactionsmentioning

confidence: 99%

Southeast Atmosphere Studies: learning from model-observation syntheses

et al. 2018

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“…In terms of other biogenic emissions from land vegetation, global simulations with an Earth system model estimated isoprene emissions between~250 and 850 TgC a −1 in the LGM depending on the assumptions on CO 2 sensitivity and temperature boundary conditions, and a decrease by 42-44% in total SOA burden compared to their pre-industrial control for their central case [136,137].…”

Section: Carbonaceous Aerosolsmentioning

confidence: 99%

“…In synthesis, the overall knowledge on LGM carbonaceous aerosol is very limited. By combining information from the source of fires with information of past vegetation [138] and linking with past and modern data from sinks like snow and ice [134], we might have the tools to evaluate and constrain models simulating past fire activity, hence potentially the emissions of carbonaceous aerosols from fire [136,139,140] and vegetation [137]. Additional information is therefore needed, to provide a constraint on the sinks of carbonaceous aerosols, from polar (and potentially some alpine) ice cores spanning the LGM.…”

Section: Carbonaceous Aerosolsmentioning

confidence: 99%

Aerosol-Climate Interactions During the Last Glacial Maximum

Albani

Balkanski

Mahowald

et al. 2018

Curr Clim Change Rep

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Purpose of Review Natural archives are imprinted with signs of the past variability of some aerosol species in connection to major climate changes. In certain cases, it is possible to use these paleo-observations as a quantitative tool for benchmarking climate model simulations. Where are we on the path to use observations and models in connection to define an envelope on aerosol feedback onto climate? Recent Findings On glacial-interglacial time scales, the major advances in our understanding refer to mineral dust, in terms of quantifying its global mass budget, as well as in estimating its direct impacts on the atmospheric radiation budget and indirect impacts on the oceanic carbon cycle. Summary Even in the case of dust, major uncertainties persist. More detailed observational studies and model intercomparison experiments such as in the Paleoclimate Modelling Intercomparison Project phase 4 will be critical in advancing the field. The inclusion of new processes such as cloud feedbacks and studies focusing on other aerosol species are also envisaged.

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“…Changes in emissions of nitrogen oxides (NO x ) from soils and lightning, and changes in photolysis rates do not alter this conclusion 16 . However, these past studies may have overestimated the reduction in emissions of BVOCs during the LGM, because they did not include the leaf-level stimulation of isoprene emissions caused by the low (185 ppmv) LGM atmospheric CO 2 , which potentially counters the effects from a cooler climate 17 18 .…”

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confidence: 99%

Understanding the glacial methane cycle

et al. 2017

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Atmospheric methane (CH4) varied with climate during the Quaternary, rising from a concentration of 375 p.p.b.v. during the last glacial maximum (LGM) 21,000 years ago, to 680 p.p.b.v. at the beginning of the industrial revolution. However, the causes of this increase remain unclear; proposed hypotheses rely on fluctuations in either the magnitude of CH4 sources or CH4 atmospheric lifetime, or both. Here we use an Earth System model to provide a comprehensive assessment of these competing hypotheses, including estimates of uncertainty. We show that in this model, the global LGM CH4 source was reduced by 28–46%, and the lifetime increased by 2–8%, with a best-estimate LGM CH4 concentration of 463–480 p.p.b.v. Simulating the observed LGM concentration requires a 46–49% reduction in sources, indicating that we cannot reconcile the observed amplitude. This highlights the need for better understanding of the effects of low CO2 and cooler climate on wetlands and other natural CH4 sources.

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Uncertainties in isoprene photochemistry and emissions: implications for the oxidative capacity of past and present atmospheres and for climate forcing agents

Cited by 12 publications

References 107 publications

Southeast Atmosphere Studies: learning from model-observation syntheses

Southeast Atmosphere Studies: learning from model-observation syntheses

Aerosol-Climate Interactions During the Last Glacial Maximum

Understanding the glacial methane cycle

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