Your search keyword '"Archer-Nicholls, Scott [0000-0002-3311-9003]"' showing total 3 results

1. Large simulated future changes in the nitrate radical under the CMIP6 SSP scenarios: implications for oxidation chemistry

Author

Scott Archer-Nicholls, Rachel Allen, Nathan Luke Abraham, Paul Thomas Griffiths, Alexander Thomas Archibald, Archer-Nicholls, Scott [0000-0002-3311-9003], Abraham, Nathan L [0000-0003-3750-3544], Griffiths, Paul T [0000-0002-1089-340X], Archibald, Alex T [0000-0001-9302-4180], and Apollo - University of Cambridge Repository

Subjects

13 Climate Action, Atmospheric Science, 3701 Atmospheric Sciences, 37 Earth Sciences

Abstract

The nitrate radical (NO3) plays an important role in the chemistry of the lower troposphere, acting as the principle oxidant during the night together with ozone. Previous model simulations suggest that the levels of NO3 have increased dramatically since the preindustrial period. Here, we show projections of the evolution of the NO3 radical from 1850–2100 using the United Kingdom Earth System Model (UKESM1) under the Coupled Model Intercomparison Project Phase 6 (CMIP6) shared socioeconomic pathway (SSP) scenarios. Our model results highlight diverse trajectories for NO3, with some scenarios and regions undergoing rapid growth of NO3 to unprecedented levels over the course of the 21st century and others seeing sharp declines. The local increases in NO3 (up to 40 ppt above the preindustrial base line) are driven not only by local changes in emissions of nitrogen oxides but have an important climate component, with NO3 being favoured in warmer future climates. The changes in NO3 lead to changes in the oxidation of important secondary organic aerosol precursors, with potential impacts on particulate matter pollution regionally and globally. This work highlights the potential for substantial future growth in NO3 and the need to better understand the formation of secondary organic aerosol (SOA) from NO3 to accurately predict future air quality and climate implications.

Published

2023

2. Minimal Climate Impacts From Short‐Lived Climate Forcers Following Emission Reductions Related to the COVID‐19 Pandemic

Author

Youngsub Matthew Shin, John Staunton Sykes, N. Luke Abraham, Alexander T. Archibald, Scott Archer-Nicholls, James Weber, Weber, James [0000-0003-0643-2026], Archer Nicholls, Scott [0000-0002-3311-9003], Abraham, Luke [0000-0003-3750-3544], Archibald, Alexander [0000-0001-9302-4180], and Apollo - University of Cambridge Repository

Subjects

Abrupt/Rapid Climate Change, Global Climate Models, Atmospheric Science, atmospheric chemistry, Ozone, 010504 meteorology & atmospheric sciences, aerosol, Climate change, Atmospheric Composition and Structure, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, complex mixtures, Atmosphere, Decadal Ocean Variability, Oceanography: Biological and Chemical, chemistry.chemical_compound, Paleoceanography, atmospheric composition, COVID‐19, Oceans, Research Letter, Sulfate aerosol, Global Change, climate, 0105 earth and related environmental sciences, Climate Change and Variability, Climatology, Aerosols, Climate Variability, Climate and Interannual Variability, Aerosols and Particles, Radiative forcing, The COVID‐19 Pandemic: Linking Health, Society and Environment, Research Letters, Aerosol, Oceanography: General, Pollution: Urban and Regional, climate change, Geophysics, chemistry, Greenhouse gas, Atmospheric chemistry, Atmospheric Processes, Environmental science, General Earth and Planetary Sciences, Troposphere: Composition and Chemistry, Oceanography: Physical

Abstract

We present an assessment of the impacts on atmospheric composition and radiative forcing of short‐lived pollutants following a worldwide decrease in anthropogenic activity and emissions comparable to what has occurred in response to the COVID‐19 pandemic, using the global composition‐climate model United Kingdom Chemistry and Aerosols Model (UKCA). Emission changes reduce tropospheric hydroxyl radical and ozone burdens, increasing methane lifetime. Reduced SO2 emissions and oxidizing capacity lead to a decrease in sulfate aerosol and increase in aerosol size, with accompanying reductions to cloud droplet concentration. However, large reductions in black carbon emissions increase aerosol albedo. Overall, the changes in ozone and aerosol direct effects (neglecting aerosol‐cloud interactions which were statistically insignificant but whose response warrants future investigation) yield a radiative forcing of −33 to −78 mWm−2. Upon cessation of emission reductions, the short‐lived climate forcers rapidly return to pre‐COVID levels; meaning, these changes are unlikely to have lasting impacts on climate assuming emissions return to pre‐intervention levels., Key Points Emission reductions are likely to have led to a global reduction in short‐lived climate forcers and tropospheric oxidizing capacityReductions in O3 and aerosol from both lower emissions and decreased sulfate oxidation resulted in a net negative radiative forcingThe radiative impacts are small and short‐lived. Longer term climate impacts must come through future sustained emission reductions

Published

2020

3. Evaluation of tropospheric ozone and ozone precursors in simulations from the HTAPII and CCMI model intercomparisons – a focus on the Indian Subcontinent

Author

Zainab Q. Hakim, Scott Archer-Nicholls, Gufran Beig, Gerd A. Folberth, Kengo Sudo, Nathan Luke Abraham, Sachin Ghude, Daven Henze, Alexander T. Archibald, Archer-Nicholls, Scott [0000-0002-3311-9003], Folberth, Gerd A [0000-0002-1075-440X], Sudo, Kengo [0000-0002-5013-4168], Abraham, Nathan Luke [0000-0003-3750-3544], Archibald, Alexander T [0000-0001-9302-4180], and Apollo - University of Cambridge Repository

Subjects

2 Aetiology, 13 Climate Action, 3701 Atmospheric Sciences, 2.2 Factors relating to the physical environment, 37 Earth Sciences

Abstract

Here we present results from an evaluation of model simulations from the International Hemispheric Transport of Air Pollution Phase II (HTAPII) and Chemistry Climate Model Initiative (CCMI) model inter-comparison projects against a comprehensive series of ground based, aircraft and satellite observations of ozone mixing ratios made at various locations across India. The study focuses on the recent past (observations from 2008–2013, models from 2008–2010) as this is most pertinent to understanding the health impacts of ozone. To our understanding this is the most comprehensive evaluation of these models' simulations of ozone across the Indian sub-continent to date. This study highlights some significant successes and challenges that the models face in representing the oxidative chemistry of the region. The multi-model range in area weighted surface ozone over the Indian subcontinent is 37.26–56.11 ppb, whilst the population weighted range is 41.38–57.5 ppb. When compared against surface observations from the Modelling Atmospheric Pollution and Networking (MAPAN) network of eight semi-urban monitoring sites spread across India, we find that the models tend to simulate higher ozone than that which is observed. However, observations of NOx and CO tend to be much higher than modelled mixing-ratios, suggesting that the underlying emissions used in the models do not characterise these regions accurately and/or that the resolution of the models is not adequate to simulate the photo-chemical environment about these surface observations. Empirical Orthogonal Function (EOF) analysis is used in order to identify the extent to which the models agree with regards to the spatio-temporal distribution of the tropospheric ozone column, derived using OMI-MLS observations. We show that whilst the models agree with the spatial pattern of the first EOF of observed tropospheric ozone column, most of the models simulate a peak in the first EOF seasonal cycle represented by principle component 1, which is later than the observed peak . This suggest a widespread systematic bias in the timing of emissions or some other unknown seasonal process. In addition to evaluating modelled ozone mixing ratios, we explore modelled emissions of NOx, CO, VOCs, and the ozone response to the emissions. We find a high degree of variation in emissions from non-anthropogenic sources (e.g. lightning NOx and biomass burning CO) between models. Total emissions of NOx and CO over India vary more between different models in the same MIP than the same model used in different MIPs, making it impossible to diagnose whether differences in modelled ozone are due to emissions or model processes. We therefore recommend targeted experiments to pinpoint the exact causes of discrepancies between modelled and observed ozone and ozone precursors for this region. To this end, a higher density of long term monitoring sites measuring not only ozone but also ozone precursors including speciated VOCs, located in more rural regions of the Indian sub-continent, would enable improvements in assessing the biases in models run at the resolution found in HTAPII and CCMI.

Published

2018