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1. Overcoming the lack of authentic standards for the quantification of biogenic secondary organic aerosol markers

Author

Daniel J. Bryant, Alfred W. Mayhew, Kelly L. Pereira, Sri Hapsari Budisulistiorini, Connor Prior, William Unsworth, David O. Topping, Andrew R. Rickard, and Jacqueline F. Hamilton

Subjects
Chemistry (miscellaneous), Environmental Chemistry, Pollution, Analytical Chemistry
Abstract

Liquid chromatography coupled to electrospray ionisation high resolution mass spectrometry is an extremely powerful technique for both targeted and non-targeted analysis of organic aerosol.

Published
2023

2. Extreme Concentrations of Nitric Oxide Control Daytime Oxidation and Quench Nocturnal Oxidation Chemistry in Delhi during Highly Polluted Episodes

Author

Beth S. Nelson, Daniel J. Bryant, Mohammed S. Alam, Roberto Sommariva, William J. Bloss, Mike J. Newland, Will S. Drysdale, Adam R. Vaughan, W. Joe F. Acton, C. Nicholas Hewitt, Leigh R. Crilley, Stefan J. Swift, Pete M. Edwards, Alastair C. Lewis, Ben Langford, Eiko Nemitz, null Shivani, Ranu Gadi, Bhola R. Gurjar, Dwayne E. Heard, Lisa K. Whalley, Ülkü A. Şahin, David C. S. Beddows, James R. Hopkins, James D. Lee, Andrew R. Rickard, and Jacqueline F. Hamilton

Subjects
Ecology, Health, Toxicology and Mutagenesis, Environmental Chemistry, Pollution, Waste Management and Disposal, Water Science and Technology
Published
2023

3. Atmospheric oxidation of new 'green' solvents part II: methyl pivalate and pinacolone

Author

Caterina Mapelli, James K. Donnelly, Úna E. Hogan, Andrew R. Rickard, Abbie T. Robinson, Fergal Byrne, Con Rob McElroy, Basile F. E. Curchod, Daniel Hollas, and Terry J. Dillon

Abstract

Lab-based experimental and computational methods were used to study the atmospheric degradation of two promising “green” solvents: pinacolone, (CH3)3CC(O)CH3, and methyl pivalate, (CH3)3CC(O)OCH3. Pulsed laser photolysis coupled to pulsed laser-induced fluorescence was used to determine absolute rate coefficients (in 10−12 cm3 molec.−1 s−1) of k1(297 K) = (1.2 ± 0.2) for OH + (CH3)3CC(O)CH3 (Reaction R1) and k2(297 K) = (1.3 ± 0.2) for OH + (CH3)3CC(O)OCH3 (Reaction R2), in good agreement with one previous experimental study. Rate coefficients for both reactions were found to increase at elevated temperature, with k1(T) adequately described by k1(297–485 K) = 2.1 × 10−12 exp(-200/T) cm3 molec.−1 s−1. k2(T) exhibited more complex behaviour, with a local minimum at around 300 K. In the course of this work, k3(295–450 K) was obtained for the well-characterised reaction OH + C2H5OH (ethanol; Reaction R3), in satisfactory agreement with the evaluated literature. UV–Vis spectroscopy experiments and computational calculations were used to explore cross-sections for (CH3)3CC(O)CH3 photolysis (Reaction R4), while (CH3)3CC(O)OCH3 showed no sign of absorption over the wavelengths of interest. Absorption cross-sections for (CH3)3CC(O)CH3, σ4(λ), in the actinic region were larger, and the maximum was red-shifted compared to estimates (methyl ethyl ketone (MEK) values) used in current state-of-science models. As a consequence, we note that photolysis (Reaction R4) is likely the dominant pathway for removal of (CH3)3CC(O)CH3 from the troposphere. Nonetheless, large uncertainties remain as quantum yields φ4(λ) remain unmeasured. Lifetime estimates based upon Reactions (R1) and (R4) span the range 2–9 d and are consequently associated with a poorly constrained estimated photochemical ozone creation potential (POCPE). In accord with previous studies, (CH3)3CC(O)OCH3 did not absorb in the actinic region, allowing for straightforward calculation of an atmospheric lifetime of ≈ 9 d and a small POCPE ≈ 11.

Published
2023

5. Analysis of Chamber Data

Author

Paul Seakins, Arnaud Allanic, Adla Jammoul, Albelwahid Mellouki, Amalia Muñoz, Andrew R. Rickard, Jean-François Doussin, Jorg Kleffmann, Juha Kangasluoma, Katrianne Lehtipalo, Kerrigan Cain, Lubna Dada, Markku Kulmala, Mathieu Cazaunau, Mike J. Newland, Mila Ródenas, Peter Wiesen, Spiro Jorga, Spyros Pandis, and Tuukka Petäjä

Abstract

In this chapter, we focus on aspects of analysis of typical simulation chamber experiments and recommend best practices in term of data analysis of simulation chamber results relevant for both gas phase and particulate phase atmospheric chemistry. The first two sections look at common gas-phase measurements of relative rates and product yields. The simple yield expressions are extended to account for product removal. In the next two sections, we examine aspects of particulate phase chemistry looking firstly at secondary organic aerosol (SOA) yields including correction for wall losses, and secondly at new particle formation using a variety of methods. Simulations of VOC oxidation processes are important components of chamber work and one wants to present methods that lead to fundamental chemistry and not to specific aspects of the chamber that the experiment was carried out in. We investigate how one can analyse the results of a simulation experiment on a well-characterized chemical system (ethene oxidation) to determine the chamber-specific corrections. Finally, we look at methods of analysing photocatalysis experiments, some with a particular focus on NOx reduction by TiO2-doped surfaces. In such systems, overall reactivity is controlled by both chemical processes and transport. Chambers can provide useful practical information, but care needs to be taken in extrapolating results to other conditions. The wider impact of surfaces on photosmog formation is also considered.

Published
2023

6. Physical and Chemical Characterization of the Chamber

Author

Rami Alfarra, Marie Camredon, Mathieu Cazaunau, Jean-François Doussin, Hendrik Fuchs, Spiro Jorga, Gordon McFiggans, Mike J. Newland, Spyros Pandis, Andrew R. Rickard, and Harald Saathoff

Abstract

In order to perform experiments in the chamber, characterization of physical properties is essential for the evaluation and interpretation of experiments. In this chapter, recommendations are given how to measure physical parameters such as temperature and pressure. For photochemistry experiments, knowledge of the radiation either provided by the sun or lamps is key to calculate photolysis frequencies. Standard protocols are described how to validate the calculation of the radiation inside the chamber using actinometry experiments. In addition, the characterization of loss processes for gas-phase species as well as for aerosol is discussed. Reference experiments can be used to test the state of the chamber. Different types of reference experiments focusing on gas-phase photo-oxidation experiments are recommended and described in detail in this chapter.

Published
2023

8. 546 A Longitudinal Case History of Skin Cancer Presentations from One of the UK's Longest Surviving Renal Transplant Patients

Author

M Rela, J Sarginson, and R Rickard

Subjects
Surgery
Abstract

Introduction The immunosuppression required by solid-organ transplant patients not only increases their risk of severe infections but also pre-disposes them to post-transplant malignancy, with skin cancers being the most frequent type. We present a longitudinal history of skin cancers in a patient who received their kidney transplant as a child and has been on immunosuppression for 50 years. Case Report The patient developed renal failure at 12 years of age and received a living donor renal transplant in 1970. He developed his first skin cancer in 2004, 34 years later. To date he has had a total of 173 lesions excised of which 123 were a non-melanoma skin cancer (NMSC) (108 basal cell carcinomas (BCCs) and 15 squamous cell carcinomas (SCCs)). None of these lesions had any high-severity features such as poor differentiation or lymphovascular invasion. Numbers of BCCs have not varied, but numbers of SCCs, Bowen's disease and Actinic Keratoses have risen gradually over time. Discussion The patient developed his first skin cancer later than has typically been reported in transplant patients and has had a ratio of BCCs to SCCs more similar to the non-transplant population. Conclusion Whilst the patient has had a large number of NMSCs over time, a recognised association for those taking immunosuppressive medications, the types and nature of his lesions mirrored that of the non-transplant population, which could relate to the fact he received his transplant as a child.

Published
2022

11. Photochemistry of 2-butenedial and 4-oxo-2-pentenal under atmospheric boundary layer conditions

Author

Gerard J. Rea, Mike J. Newland, Bernard T. Golding, Ian Barnes, Lars P. Thüner, Andrew R. Rickard, Alistair P. Henderson, and John C. Wenger

Subjects
Ozone, Photoisomerization, Photodissociation, General Physics and Astronomy, Maleic anhydride, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Ring (chemistry), Photochemistry, 01 natural sciences, E-Z notation, 0104 chemical sciences, chemistry.chemical_compound, Boundary layer, chemistry, 13. Climate action, Yield (chemistry), Physical and Theoretical Chemistry, 0210 nano-technology
Abstract

Unsaturated 1,4-dicarbonyl compounds, such as 2-butenedial and 4-oxo-2-pentenal are produced in the atmospheric boundary layer from the oxidation of aromatic compounds and furans. These species are expected to undergo rapid photochemical processing, affecting atmospheric composition. In this study, the photochemistry of (E)-2-butenedial and both E and Z isomers of 4-oxo-2-pentenal was investigated under natural sunlight conditions at the large outdoor atmospheric simulation chamber EUPHORE. Photochemical loss rates, relative to j(NO2), are determined to be j((E)-2-butenedial)/j(NO2) = 0.14 (±0.02), j((E)-4-oxo-2-pentenal)/j(NO2) = 0.18 (±0.01), and j((Z)-4-oxo-2-pentenal)/j(NO2) = 0.20 (±0.03). The major products detected for both species are a furanone (30–42%) and, for (E)-2-butenedial, maleic anhydride (2,5-furandione) (12–14%). The mechanism appears to proceed predominantly via photoisomerization to a ketene–enol species following γ-H abstraction. The lifetimes of the ketene–enol species in the dark from 2-butenedial and 4-oxo-2-pentenal are determined to be 465 s and 235 s, respectively. The ketene–enol can undergo ring closure to yield the corresponding furanone, or further unimolecular rearrangement which can subsequently form maleic anhydride. A minor channel (10–15%) also appears to form CO directly. This is presumed to be via a molecular elimination route of an initial biradical intermediate formed in photolysis, with an unsaturated carbonyl (detected here but not quantified) as co-product. α-Dicarbonyl and radical yields are very low, which has implications for ozone production from the photo-oxidation of unsaturated 1,4-dicarbonyls in the boundary layer. Photochemical removal is determined to be the major loss process for these species in the boundary layer with lifetimes of the order of 10–15 minutes, compared to >3 hours for reaction with OH.

Published
2019

12. High time resolution offline analysis of biogenic secondary organic aerosol in Guangzhou, China

Author

Andrew R. Rickard, Erin White, Wei Deng, Xinming Wang, Wei Song, Sainan Wang, Atallah Elzein, Jacqueline F. Hamilton, Amy Watkins, Daniel J. Bryant, Mike J. Newland, and Kelly L. Pereira

Subjects
Environmental science, Offline analysis, Time resolution, China, Aerosol, Remote sensing
Abstract

PM2.5 is considered to be the most dangerous form of air pollution and is formed of a complex mixture of both primary and secondary species, from both biogenic and anthropogenic sources. Organic aerosol, comprised of modern carbon has been shown to dominate even in urban settings, but sources and formation mechanism of these biogenic aerosol in the ambient atmosphere remain uncertain. The collection and offline analysis of PM2.5 aerosol samples allows for highly detailed molecular level compositional information to be obtained, but at the cost of time resolution. Previous studies have collected 23-hour offline filters, which although allowing for seasonal changes to be studied, cannot resolve diurnal variations. However, due to recent advances in high-resolution mass spectrometers, the time resolution of offline filters can now be increased. This study utilises high time resolution offline filters collected in Guangzhou, China across two campaigns during summer and winter. Filters were collected every 2 hours during the day (06:00 – 21:00), with a longer collection overnight (21:00-06:00), alongside a suite of complementary gas phase measurements. Guangzhou represents an interesting case study for biogenic secondary organic aerosol (BSOA) especially biogenic-anthropogenic interactions due to its tropical location and high levels of flora, but also located in one of the most densely populated regions of the world within the Guangdong-Hong Kong-Macau Greater Bay area, with a combined population of 71.2 million people.This study presents ultra-high-performance liquid chromatography, high-resolution mass spectrometry measurements of BSOA tracers identified in the ambient PM2.5 samples at the highest time resolution studied so far. A library of 180 potential BSOA tracers from isoprene, monoterpenes and sesquiterpenes was developed containing acid species (CHO), organosulfates (CHOS) and nitrooxy organosulfates (CHOSN). The BSOA tracers were quantified using a mixture of authentic standards, proxy standards and modelled RIE factors for accurate quantification. Matrix suppression factors were also determined for both CHO and CHOS/CHOSN species, splitting the compounds into groups based on their retention time (RT), with species eluting before 2 min showing the largest matrix suppression.Strong diurnal variations were observed for some species while others showed little or no diurnal variation suggesting nonlocal sources, and as such provides insight into how long-range sources can affect BSOA concentrations. Tracers were also correlated to anthropogenic pollutants such as NOX and SO2 as well as sulfate and nitrate measured via ion chromatography, improving our understanding of biogenic-anthropogenic interactions. Comparisons between summer and winter allowed insight into seasonal processes and concentrations, with the potential for different long-range sources. Finally, this study presents comparisons to a growing field of offline BSOA measurements, providing a more comprehensive picture of the contributions BSOA makes to PM2.5 concentrations.

Published
2021

13. O3: EVALUATION OF A 3D PRINTED BIO-ARTIFICIAL MUSCLE-ORGANOID FOR TRAUMA RESEARCH

Author

R Rickard, AM Spear, Rmt Staruch, Joanne Edwards, and M Thompson

Subjects
3d printed, biology, business.industry, Trauma research, Skeletal Myocytes, Fibrin, Self-healing hydrogels, biology.protein, Organoid, Medicine, Myocyte, Surgery, Artificial muscle, business, Biomedical engineering
Abstract

Introduction Organoid models serve as a robust platform for investigating injury and disease in vitro. Currently, representative models of injury are lacking to investigate the effects of traumatic damage to organs and tissues. Here we describe a three-dimensional in vitro model of high strain rate loading seen in traumatic blast injury. Method 3D printing resins were tested for Young's Modulus & Poisson Ratio using a universal testing Organoids were then loaded into a 3D Printed bioreactor for high strain rate loading using a split Hopkinson pressure bar device. machine and digital image. Euler beam theory was used to evaluate post deflection. C2C12 myoblasts were seeded in fibrin hydrogels around 3D printed posts using a custom designed jig. High strain rate loading was applied to constructs, then qPCR & Fluorescent Live/Dead staining was utilised to demonstrate cell alignment and myotube formation. Result Young's modulus of Flexible resin was 11.51Mpa. Differentiated C2C12 myoblasts were capable of alignment between posts and expression of key markers of differentiation shown by qPCR & imaging. MYH5, MYH2 & MYH1 all had a > 1.5 old increase in expression compared to undifferentiated controls. Organoids were capable of survival in bioreactor casings for over 24 hours and were intact after application of high strain rate loading. Conclusion This work demonstrates the first use of a 3D printed organoid in vitro model to investigate high strain rate loading for trauma research. This organoid is capable of high throughput analysis to facilitate genomic and protein level expression analysis. Take-home message This work demonstrates the first use of a 3D printed organoid in vitro model to investigate high strain rate loading for trauma research.

Published
2021

14. Key Role of NO

Author

Jacqueline F, Hamilton, Daniel J, Bryant, Peter M, Edwards, Bin, Ouyang, Thomas J, Bannan, Archit, Mehra, Alfred W, Mayhew, James R, Hopkins, Rachel E, Dunmore, Freya A, Squires, James D, Lee, Mike J, Newland, Stephen D, Worrall, Asan, Bacak, Hugh, Coe, Carl, Percival, Lisa K, Whalley, Dwayne E, Heard, Eloise J, Slater, Roderic L, Jones, Tianqu, Cui, Jason D, Surratt, Claire E, Reeves, Graham P, Mills, Sue, Grimmond, Yele, Sun, Weiqi, Xu, Zongbo, Shi, and Andrew R, Rickard

Subjects
Aerosols, Hemiterpenes, Nitrates, Beijing, Butadienes
Abstract

The formation of isoprene nitrates (IsN) can lead to significant secondary organic aerosol (SOA) production and they can act as reservoirs of atmospheric nitrogen oxides. In this work, we estimate the rate of production of IsN from the reactions of isoprene with OH and NO

Published
2021

15. Sources of non-methane hydrocarbons in surface air in Delhi, India

Author

W. Joe F. Acton, Adam R. Vaughan, Jacqueline F. Hamilton, Ben Langford, Eiko Nemitz, Gareth J. Stewart, Andrew R. Rickard, Ernesto Reyes-Villegas, James R. Hopkins, Beth S. Nelson, Will Drysdale, Shivani, James D. Lee, Rachel Dunmore, C. Nicholas Hewitt, Neil Mullinger, and Ranu Gadi

Subjects
Pollution, Diesel exhaust, 010504 meteorology & atmospheric sciences, media_common.quotation_subject, Air pollution, BTEX, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, Atmospheric Sciences, Diesel fuel, Environmental chemistry, medicine, Mixing ratio, Environmental science, Physical and Theoretical Chemistry, Gasoline, Air quality index, 0105 earth and related environmental sciences, media_common
Abstract

Rapid economic growth and development have exacerbated air quality problems across India, driven by many poorly understood pollution sources and understanding their relative importance remains critical to characterising the key drivers of air pollution. A comprehensive suite of measurements of 90 non-methane hydrocarbons (NMHCs) (C2–C14), including 12 speciated monoterpenes and higher molecular weight monoaromatics, were made at an urban site in Old Delhi during the pre-monsoon (28-May to 05-Jun 2018) and post-monsoon (11 to 27-Oct 2018) seasons using dual-channel gas chromatography (DC-GC-FID) and two-dimensional gas chromatography (GC×GC-FID). Significantly higher mixing ratios of NMHCs were measured during the post-monsoon campaign, with a mean night-time enhancement of around 6. Like with NOx and CO, strong diurnal profiles were observed for all NMHCs, except isoprene, with very high NMHC mixing ratios between 35–1485 ppbv. The sum of mixing ratios of benzene, toluene, ethylbenzene and xylenes (BTEX) routinely exceeded 100 ppbv at night during the post-monsoon period, with a maximum measured mixing ratio of monoaromatic species of 370 ppbv. The mixing ratio of highly reactive monoterpenes peaked at around 6 ppbv in the post-monsoon campaign and correlated strongly with anthropogenic NMHCs, suggesting a strong non-biogenic source in Delhi. A detailed source apportionment study was conducted which included regression analysis to CO, acetylene and other NMHCs, hierarchical cluster analysis, EPA UNMIX 6.0, principal component analysis/absolute principal component scores (PCA/APCS) and comparison with NMHC ratios (benzene/toluene and i-/n-pentane) in ambient samples to liquid and solid fuels. These analyses suggested the primary source of anthropogenic NMHCs in Delhi was from traffic emissions (petrol and diesel), with average mixing ratio contributions from Unmix and PCA/APCS models of 38% from petrol, 14% from diesel and 32% from liquified petroleum gas (LPG) with a smaller contribution (16%) from solid fuel combustion. Detailed consideration of the underlying meteorology during the campaigns showed that the extreme night-time mixing ratios of NMHCs during the post-monsoon campaign were the result of emissions into a very shallow and stagnant boundary layer. The results of this study suggest that despite widespread open burning in India, traffic-related petrol and diesel emissions remain the key drivers of gas-phase urban air pollution in Delhi.

Published
2020

16. Supplementary material to 'Emissions of non-methane volatile organic compounds from combustion of domestic fuels in Delhi, India'

Author

Gareth J. Stewart, W. Joe F. Acton, Beth S. Nelson, Adam R. Vaughan, James R. Hopkins, Rahul Arya, Arnab Mondal, Ritu Jangirh, Sakshi Ahlawat, Lokesh Yadav, Sudhir K. Sharma, Rachel E. Dunmore, Siti S. M. Yunus, C. Nicholas Hewitt, Eiko Nemitz, Neil Mullinger, Ranu Gadi, Lokesh K. Sahu, Nidhi Tripathi, Andrew R. Rickard, James D. Lee, Tuhin K. Mandal, and Jacqueline F. Hamilton

Published
2020

17. Supplementary material to 'Emissions of intermediate-volatility and semi-volatile organic compounds from domestic fuels used in Delhi, India'

Author

Gareth J. Stewart, Beth S. Nelson, W. Joe F. Acton, Adam R. Vaughan, Naomi J. Farren, James R. Hopkins, Martyn W. Ward, Stefan J. Swift, Rahul Arya, Arnab Mondal, Ritu Jangirh, Sakshi Ahlawat, Lokesh Yadav, Sudhir K. Sharma, Siti S. M. Yunus, C. Nicholas Hewitt, Eiko Nemitz, Neil Mullinger, Ranu Gadi, Lokesh K. Sahu, Nidhi Tripathi, Andrew R. Rickard, James D. Lee, Tuhin K. Mandal, and Jacqueline F. Hamilton

Published
2020

19. Estimation of rate coefficients for the reactions of O3 with unsaturated organic compounds for use in automated mechanism construction

Author

R. Valorso, Bernard Aumont, Andrew R. Rickard, Michael E. Jenkin, and Mike J. Newland

Subjects
chemistry.chemical_classification, Atmospheric Science, Ozone, 010504 meteorology & atmospheric sciences, Double bond, Conjugated system, 010402 general chemistry, Branching (polymer chemistry), 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Computational chemistry, 13. Climate action, Ozonide, 0105 earth and related environmental sciences
Abstract

Reaction with ozone (O3) is an important removal process for unsaturated volatile organic compounds (VOCs) in the atmosphere. Rate coefficients for reactions of O3 with VOCs are therefore essential parameters for chemical mechanisms used in chemistry transport models. Updated and extended structure–activity relationship (SAR) methods are presented for the reactions of O3 with mono- and poly-unsaturated organic compounds. The methods are optimized using a preferred set of data including reactions of O3 with 222 unsaturated compounds. For conjugated dialkene structures, site specific rates are defined, and for isolated poly-alkenes rates are defined for each double bond to determine the branching ratios for primary ozonide formation. The information can therefore guide the representation of the O3 reactions in the next generation of explicit detailed chemical mechanisms.

Published
2020

20. Aromatic Photo-oxidation, A New Source of Atmospheric Acidity

Author

Milagros Ródenas, Xinming Wang, Mónica Vázquez, Andrew R. Rickard, Sainan Wang, Mike J. Newland, Jacqueline F. Hamilton, Liming Wang, Amalia Muñoz, and Wei Deng

Subjects
Chemical models, Organic chemicals, Chemistry, Formic acid, Atmosphere, Biomass, Oxidation reduction, General Chemistry, 010501 environmental sciences, 01 natural sciences, chemistry.chemical_compound, 13. Climate action, Environmental chemistry, mental disorders, Environmental Chemistry, Organic Chemicals, Oxidation-Reduction, Earth (classical element), 0105 earth and related environmental sciences
Abstract

Formic acid (HCOOH), one of the most important and ubiquitous organic acids in the Earth's atmosphere, contributes substantially to atmospheric acidity and affects pH-dependent reactions in the aqueous phase. However, based on the current mechanistic understanding, even the most advanced chemical models significantly underestimate the HCOOH concentrations when compared to ambient observations at both ground-level and high altitude, thus underrating its atmospheric impact. Here we reveal new chemical pathways to HCOOH formation from reactions of both O

Published
2020

22. Evaluation of the Chemical Composition of Gas and Particle Phase Products of Aromatic Oxidation

Author

Archit Mehra, Yuwei Wang, Jordan E. Krechmer, Andrew Lambe, Francesca Majluf, Melissa A. Morris, Michael Priestley, Thomas J. Bannan, Daniel J. Bryant, Kelly L. Pereira, Jacqueline F. Hamilton, Andrew R. Rickard, Mike J. Newland, Harald Stark, Philip Croteau, John T. Jayne, Douglas R. Worsnop, Manjula R. Canagaratna, Lin Wang, and Hugh Coe

Abstract

Aromatic volatile organic compounds (VOC) are key anthropogenic pollutants emitted to the atmosphere and are important for both ozone and secondary organic aerosol (SOA) formation in urban areas. Recent studies have indicated that aromatic hydrocarbons may follow previously unknown oxidation chemistry pathways, including autoxidation that can lead to the formation of highly oxidised products. In this study we evaluate the gas and particle phase ions formed during the hydroxyl radical oxidation of substituted C9-aromatic isomers (1,3,5-trimethyl benzene, 1,2,4-trimethyl benzene, propyl benzene and isopropyl benzene) and a substituted polyaromatic hydrocarbon (1-methyl naphthalene) under low and medium NOx conditions. The majority of product signal in both gas and particle phases comes from ions which are common to all precursors, though signal distributions are distinct for different VOCs. Gas and particle phase composition are distinct from one another, and comparison with the near explicit gas phase Master Chemical Mechanism (MCMv3.3.1) highlights a range of missing highly oxidised products in the pathways. In the particle phase, the bulk of product signal from all precursors comes from ring scission ions, many of which have undergone further oxidation to form HOMs. Under perturbation of OH oxidation with increased NOx, the contribution of HOM ion signals to the particle phase signal remains elevated for more substituted aromatic precursors. Up to 25 % of product signal comes from ring-retaining ions including highly oxygenated organic molecules (HOMs); this is most important for the more substituted aromatics. Unique products are a minor component in these systems, and many of the dominant ions have ion formulae concurrent with other systems, highlighting the challenges in utilising marker ions for SOA.

Published
2020

24. Rainforest-like Atmospheric Chemistry in a Polluted Megacity

Author

W. Joe F. Acton, Eloise Slater, Mathew J. Evans, James D. Lee, Mike J. Newland, Jason D. Surratt, Thomas J. Bannan, Peter Edwards, Rachel Dunmore, William Dixon, C. Nicholas Hewitt, Andrew R. Rickard, Will Drysdale, Freya Squires, Stephen D. Worrall, Daniel J. Bryant, Dwayne E. Heard, Archit Mehra, Xinming Wang, Hugh Coe, Alastair C. Lewis, Lisa K. Whalley, Asan Bacak, James R. Hopkins, Tianqu Cui, Robert Woodward-Massey, Jacqueline F. Hamilton, Peter D. Ivatt, Ben Langford, Chunxiang Ye, and Carl J. Percival

Subjects
chemistry.chemical_classification, Pollutant, Ozone, 010504 meteorology & atmospheric sciences, Air pollution, medicine.disease_cause, 01 natural sciences, Aerosol, chemistry.chemical_compound, Megacity, chemistry, Atmospheric chemistry, Environmental chemistry, medicine, Environmental science, Volatile organic compound, Air quality index, 0105 earth and related environmental sciences
Abstract

The impact of volatile organic compound (VOC) emissions to the atmosphere on the production of secondary pollutants, such as ozone and secondary organic aerosol (SOA), is mediated by the concentration of nitric oxide (NO). Polluted urban atmospheres are typically considered to be high-NO environments, while remote regions such as rainforests, with minimal anthropogenic influences, are considered to be low-NO. Policy to reduce urban air pollution is typically developed assuming that the chemistry is controlled by the high-NO regime. However, our observations from central Beijing show that this simplistic separation of regimes is flawed. Despite being in one of the largest megacities in the world, we observe significant formation of gas and aerosol phase oxidation products associated with the low-NO rainforest-like regime during the afternoon. This is caused by a surprisingly low concentration of NO, coupled with high concentrations of VOCs and of the atmospheric oxidant hydroxyl (OH). Box model calculations suggest that during the morning high-NO chemistry predominates (95 %) but in the afternoon low-NO chemistry plays a greater role (30 %). With increasing global emphasis on reducing air pollution, the modelling tools used to develop urban air quality policy need to adequately represent both high- and low-NO regimes if they are to have utility.

Published
2020

25. Trends in stabilisation of Criegee intermediates from alkene ozonolysis

Author

Beth S. Nelson, Amalia Muñoz, Joan Tárrega, Mike J. Newland, Milagros Ródenas, Teresa Vera, and Andrew R. Rickard

Subjects
chemistry.chemical_classification, education.field_of_study, Primary (chemistry), Ozonolysis, 010504 meteorology & atmospheric sciences, Chemistry, Alkene, Radical, Population, General Physics and Astronomy, 010402 general chemistry, Photochemistry, 01 natural sciences, Decomposition, 0104 chemical sciences, chemistry.chemical_compound, 13. Climate action, Tropospheric chemistry, Ozonide, Physical and Theoretical Chemistry, education, 0105 earth and related environmental sciences
Abstract

Criegee Intermediates (CI), formed in the ozonolysis of alkenes, play a central role in tropospheric chemistry as an important source of radicals, with stabilised CI (SCI) able to participate in bimolecular reactions, affecting climate through the formation of inorganic and organic aerosol. However, total SCI yields have only been determined for a few alkene systems, while speciated SCI yields from asymmetrical alkenes are almost entirely unknown. Here we report for the first time a systematic experimental exploration of the stabilisation of CH2OO and (CH3)2COO CI, formed from ten alkene–ozone systems with a range of different sizes and structures, under atmospherically relevant conditions in the EUPHORE chamber. Experiments in the presence of excess SO2 (an SCI scavenger) determined total SCI yields from each alkene–ozone system. Comparison of primary carbonyl yields in the presence/absence of SO2 determined the stabilisation fraction of a given CI. The results show that the stabilisation of a given CI increases as the size of the carbonyl co-product increases. This is interpreted in terms of the nascent population of CI formed following decomposition of the primary ozonide (POZ) having a lower mean energy distribution when formed with a larger carbonyl co-product, as more of the energy from the POZ is taken by the carbonyl. These findings have significant implications for atmospheric modelling of alkene ozonolysis. Higher stabilisation of small CI formed from large alkenes is expected to lead to lower radical yields from CI decomposition, and higher SCI concentrations, increasing the importance of SCI bimolecular reactions.

Published
2020
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27. Perspective on Mechanism Development and Structure-Activity Relationships for Gas-Phase Atmospheric Chemistry

Author

Luc Vereecken, Max R. McGillen, Bernard Aumont, Abdelwahid Mellouki, Andrew R. Rickard, Joseph W. Bozzelli, Ian Barnes, Mark Jacob Goldman, Sasha Madronich, William P. L. Carter, Bénédicte Picquet-Varrault, William H. Green, Timothy J. Wallington, William R. Stockwell, and John J. Orlando

Subjects
Sustainable development, Structure (mathematical logic), 010504 meteorology & atmospheric sciences, Chemistry, Organic Chemistry, Perspective (graphical), Atmospheric model, 010402 general chemistry, 01 natural sciences, Biochemistry, 0104 chemical sciences, Gas phase, Inorganic Chemistry, Development (topology), 13. Climate action, Mechanism (philosophy), Atmospheric chemistry, Biochemical engineering, Physical and Theoretical Chemistry, 0105 earth and related environmental sciences
Abstract

This perspective gives our views on general aspects and future directions of gas‐phase atmospheric chemical kinetic mechanism development, emphasizing on the work needed for the sustainable development of chemically detailed mechanisms that reflect current kinetic, mechanistic, and theoretical knowledge. Current and future mechanism development efforts and research needs are discussed, including software‐aided autogeneration and maintenance of kinetic models as a future‐proof approach for atmospheric model development. There is an overarching need for the evaluation and extension of structure‐activity relationships (SARs) that predict the properties and reactions of the many multifunctionalized compounds in the atmosphere that are at the core of detailed mechanisms, but for which no direct chemical data are available. Here, we discuss the experimental and theoretical data needed to support the development of mechanisms and SARs, the types of SARs relevant to atmospheric chemistry, the current status and limitations of SARs for various types of atmospheric reactions, the status of thermochemical estimates needed for mechanism development, and our outlook for the future. The authors have recently formed a SAR evaluation working group to address these issues.

Published
2018

28. Supplementary material to 'Strong anthropogenic control of secondary organic aerosol formation from isoprene in Beijing'

Author

Daniel J. Bryant, William J. Dixon, James R. Hopkins, Rachel E. Dunmore, Kelly L. Pereira, Marvin Shaw, Freya A. Squires, Thomas J. Bannan, Archit Mehra, Stephen D. Worrall, Asan Bacak, Hugh Coe, Carl J. Percival, Lisa K. Whalley, Dwayne E. Heard, Eloise J. Slater, Bin Ouyang, Tianqu Cui, Jason D. Surratt, Di Liu, Zongbo Shi, Roy Harrison, Yele Sun, Weiqi Xu, Alastair C. Lewis, James D. Lee, Andrew R. Rickard, and Jacqueline F. Hamilton

Published
2019

30. Estimation of rate coefficients and branching ratios for reactions of organic peroxy radicals for use in automated mechanism construction

Author

M. E. Jenkin, R. Valorso, B. Aumont, and A. R. Rickard

Subjects
chemistry.chemical_classification, Atmospheric Science, 010504 meteorology & atmospheric sciences, Chemistry, Branching fraction, Radical, Kinetics, 010402 general chemistry, Branching (polymer chemistry), 01 natural sciences, lcsh:QC1-999, 0104 chemical sciences, lcsh:Chemistry, Hydrocarbon, lcsh:QD1-999, Computational chemistry, Isomerization, lcsh:Physics, 0105 earth and related environmental sciences
Abstract

Organic peroxy radicals (RO2), formed from the degradation of hydrocarbons and other volatile organic compounds (VOCs), play a key role in tropospheric oxidation mechanisms. Several competing reactions may be available for a given RO2 radical, the relative rates of which depend on both the structure of RO2 and the ambient conditions. Published kinetics and branching ratio data are reviewed for the bimolecular reactions of RO2 with NO, NO2, NO3, OH and HO2; and for their self-reactions and cross-reactions with other RO2 radicals. This information is used to define generic rate coefficients and structure–activity relationship (SAR) methods that can be applied to the bimolecular reactions of a series of important classes of hydrocarbon and oxygenated RO2 radicals. Information for selected unimolecular isomerization reactions (i.e. H-atom shift and ring-closure reactions) is also summarized and discussed. The methods presented here are intended to guide the representation of RO2 radical chemistry in the next generation of explicit detailed chemical mechanisms.

Published
2019

31. Atmospheric ethanol in London and the potential impacts of future fuel formulations

Author

James D. Lee, Andrew R. Rickard, Dwayne E. Heard, Rachel Dunmore, Jacqueline F. Hamilton, Alastair C. Lewis, Richard T. Lidster, Lisa K. Whalley, James R. Hopkins, Tomás Sherwen, and Mathew J. Evans

Subjects
Chromatography, Gas, Ozone, 010504 meteorology & atmospheric sciences, Chemical transport model, Meteorology, Air pollution, Acetaldehyde, 010501 environmental sciences, medicine.disease_cause, 01 natural sciences, chemistry.chemical_compound, Air Pollution, London, medicine, Physical and Theoretical Chemistry, Gasoline, Air quality index, NOx, 0105 earth and related environmental sciences, Pollutant, Ethanol, chemistry, Environmental chemistry, Linear Models, Nitrogen Oxides, Seasons, Oxidation-Reduction
Abstract

There is growing global consumption of non-fossil fuels such as ethanol made from renewable biomass. Previous studies have shown that one of the main air quality disadvantages of using ethanol blended fuels is a significant increase in the production of acetaldehyde, an unregulated and toxic pollutant. Most studies on the impacts of ethanol blended gasoline have been carried out in the US and Brazil, with much less focus on the UK and Europe. We report time resolved measurements of ethanol in London during the winter and summer of 2012. In both seasons the mean mixing ratio of ethanol was around 5 ppb, with maximum values over 30 ppb, making ethanol currently the most abundant VOC in London air. We identify a road transport related source, with ‘rush-hour’ peaks observed. Ethanol is strongly correlated with other road transport-related emissions, such as small aromatics and light alkanes, and has no relationship to summer biogenic emissions. To determine the impact of road transport-related ethanol emission on secondary species (i.e. acetaldehyde and ozone), we use both a chemically detailed box model (incorporating the Master Chemical Mechanism, MCM) and a global and nested regional scale chemical transport model (GEOS-Chem), on various processing time scales. Using the MCM model, only 16% of the modelled acetaldehyde was formed from ethanol oxidation. However, the model significantly underpredicts the total levels of acetaldehyde, indicating a missing primary emission source, that appears to be traffic-related. Further support for a primary emission source comes from the regional scale model simulations, where the observed concentrations of ethanol and acetaldehyde can only be reconciled with the inclusion of large primary emissions. Although only constrained by one set of observations, the regional modelling suggests a European ethanol source similar in magnitude to that of ethane (∼60 Gg per year) and greater than that of acetaldehyde (∼10 Gg per year). The increased concentrations of ethanol and acetaldehyde from primary emissions impacts both radical and NOx cycling over Europe, resulting in significant regional impacts on NOy speciation and O3 concentrations, with potential changes to human exposure to air pollutants.

Published
2016

32. Introduction to Special Issue – In-depth study of air pollution sources and processes within Beijing and its surrounding region (APHH-Beijing)

Author

Zongbo Shi, Tuan Vu, Simone Kotthaus, Sue Grimmond, Roy M. Harrison, Siyao Yue, Tong Zhu, James Lee, Yiqun Han, Matthias Demuzere, Rachel E. Dunmore, Lujie Ren, Di Liu, Yuanlin Wang, Oliver Wild, James Allan, Janet Barlow, David Beddows, William J. Bloss, David Carruthers, David C. Carslaw, Lia Chatzidiakou, Leigh Crilley, Hugh Coe, Tie Dai, Ruth Doherty, Fengkui Duan, Pingqing Fu, Baozhu Ge, Maofa Ge, Daobo Guan, Jacqueline F. Hamilton, Kebin He, Mathew Heal, Dwayne Heard, C. Nicholas Hewitt, Min Hu, Dongsheng Ji, Xujiang Jiang, Rod Jones, Markus Kalberer, Frank J. Kelly, Louisa Kramer, Ben Langford, Chun Lin, Alastair C. Lewis, Jie Li, Weijun Li, Huan Liu, Miranda Loh, Keding Lu, Graham Mann, Gordon McFiggans, Mark Miller, Graham Mills, Paul Monk, Eiko Nemitz, Fionna O'Connor, Bin Ouyang, Paul I. Palmer, Carl Percival, Olalekan Popoola, Claire Reeves, Andrew R. Rickard, Longyi Shao, Guangyu Shi, Dominick Spracklen, David Stevenson, Yele Sun, Zhiwei Sun, Shu Tao, Shengrui Tong, Qingqing Wang, Wenhua Wang, Xinming Wang, Zifang Wang, Lisa Whalley, Xuefang Wu, Zhijun Wu, Pinhua Xie, Fumo Yang, Qiang Zhang, Yanli Zhang, Yuanhang Zhang, and Mei Zheng

Abstract

APHH-Beijing (Atmospheric Pollution and Human Health in a Chinese Megacity) is an international collaborative project to examine the emissions, processes and health effects of air pollution in Beijing. The four research themes of APHH-China are: (1) sources and emissions of urban atmospheric pollution; (2) processes affecting urban atmospheric pollution; (3) exposure science and impacts on health; and (4) interventions and solutions to reduce health impacts. Themes 1 and 2 are closely integrated and support Theme 3, while Themes 1–3 provide scientific data for Theme 4 on the development of cost-effective solutions. A key activity within APHH-Beijing was the two month-long intensive field campaigns at two sites: (i) central Beijing, and (ii) rural Pinggu. The coordinated campaigns provided observations of the atmospheric chemistry and physics in and around Beijing during November–December 2016 and May–June 2017. The campaigns were complemented by numerical air quality modelling and air quality and meteorology data at the 12 national monitoring stations in Beijing. This introduction paper provides an overview of (i) APHH-Beijing programme, (ii) the measurement and modelling activities performed as part of it in Beijing, and (iii) the air quality and meteorological conditions during the two field campaigns. The winter campaign was characterized by high PM2.5 pollution events whereas the summer experienced high ozone pollution events. Air quality was poor during the winter campaign, but less severe than in the same period in 2015 when there were a number of major pollution episodes. PM2.5 levels were relatively low during the summer period, matching the cleanest periods over the previous five years. Synoptic scale meteorological analysis suggests that the greater stagnation and weak southerly circulation in November/December 2016 may have contributed to the poor air quality.

Published
2018

33. Estimation of rate coefficients and branching ratios for gas-phase reactions of OH with aromatic organic compounds for use in automated mechanism construction

Author

Michael E. Jenkin, Richard Valorso, Bernard Aumont, Andrew R. Rickard, and Timothy J. Wallington

Abstract

Reaction with the hydroxyl (OH) radical is the dominant removal process for volatile organic compounds (VOCs) in the atmosphere. Rate coefficients for the reactions of OH with VOCs are therefore essential parameters for chemical mechanisms used in chemistry-transport models, and are required more generally for impact assessments involving estimation of atmospheric lifetimes or oxidation rates for VOCs. A structure-activity relationship (SAR) method is presented for the reactions of OH with aromatic organic compounds, with the reactions of aliphatic organic compounds considered in the preceding companion paper. The SAR is optimized using a preferred set of data including reactions of OH with 67 monocyclic aromatic hydrocarbons and oxygenated organic compounds. In each case, the rate coefficient is defined in terms of a summation of partial rate coefficients for H abstraction or OH addition at each relevant site in the given organic compound, so that the attack distribution is defined. The SAR can therefore guide the representation of the OH reactions in the next generation of explicit detailed chemical mechanisms. Rules governing the representation of the reactions of the product radicals under tropospheric conditions are also summarized, specifically the rapid reaction sequences initiated by their reactions with O2.

Published
2018

38. The atmospheric impacts of monoterpene ozonolysis on global stabilised Criegee intermediate budgets and SO2 oxidation: experiment, theory and modelling

Author

Mike J. Newland, Andrew R. Rickard, Tomás Sherwen, Mathew J. Evans, Luc Vereecken, Amalia Muñoz, Milagros Ródenas, and William J. Bloss

Subjects
010504 meteorology & atmospheric sciences, 13. Climate action, 010501 environmental sciences, 01 natural sciences, 0105 earth and related environmental sciences
Abstract

The gas-phase reaction of alkenes with ozone is known to produce stabilised Criegee intermediates (SCIs). These biradical/zwitterionic species have the potential to act as atmospheric oxidants for trace pollutants such as SO2, enhancing the formation of sulfate aerosol with impacts on air quality and health, radiative transfer and climate. However, the importance of this chemistry is uncertain as a consequence of limited understanding of the abundance and atmospheric fate of SCIs. In this work we apply experimental, theoretical and numerical modelling methods to quantify the atmospheric impacts, abundance, and fate, of the structurally diverse SCIs derived from the ozonolysis of monoterpenes, the second most abundant group of unsaturated hydrocarbons in the atmosphere. We have investigated the removal of SO2 by SCI formed from the ozonolysis of three monoterpenes (-pinene, -pinene and limonene) in the presence of varying amounts of water vapour in large-scale simulation chamber experiments. The SO2 removal displays a clear dependence on water vapour concentration, but this dependence is not linear across the range of [H2O] explored. At low [H2O] a strong dependence of SO2 removal on [H2O] is observed, while at higher [H2O] this dependence becomes much weaker. This is interpreted as being caused by the production of a variety of structurally (and hence chemically) different SCI in each of the systems studied, each displaying different rates of reaction with water and of unimolecular rearrangement/decomposition. The determined rate constants, k(SCI+H2O), for those SCI that react primarily with H2O range from 4–310 × 10−15 cm3 s−1. For those SCI that predominantly react unimolecularly, determined rates range from 130–240 s−1. These values are in line with previous results for the (analogous) stereo-specific SCI system of syn/anti-CH3CHOO. The experimental results are interpreted through theoretical studies of the SCI unimolecular reactions and bimolecular reactions with H2O, characterised for -pinene and -pinene at the M06-2X/aug-cc-pVTZ level of theory. The theoretically derived rates agree with the experimental results within the uncertainties. A global modelling study, applying the experimental results within the GEOS-Chem chemical transport model, suggests that > 98 % of the total monoterpene derived global SCI burden is comprised of SCI whose structure determines that they react slowly with water, and whose atmospheric fate is dominated by unimolecular reactions. Seasonally averaged boundary layer concentrations of monoterpene-derived SCI reach up to 1.2 × 104 cm−3 in regions of elevated monoterpene emissions in the tropics. Reactions of monoterpene derived SCI with SO2 account for

Published
2017

39. Insights into the Formation and Evolution of Individual Compounds in the Particulate Phase during Aromatic Photo-Oxidation

Author

Teresa Vera, Milagros Ródenas, William J. Bloss, Kevin Wyche, Andrew R. Rickard, M. S. Alam, Amalia Muñoz, Marie Camredon, Mónica Vázquez, Jacqueline F. Hamilton, Martyn W. Ward, Esther Borrás, Kelly L. Pereira, and Université Paris-Est Créteil Val-de-Marne - Paris 12 (UPEC UP12)

Subjects
Time Factors, Light, Allylbenzene Derivatives, Anisoles, Photochemistry, Mass spectrometry, Hydrocarbons, Aromatic, behavioral disciplines and activities, Nitrophenols, chemistry.chemical_compound, Phase (matter), Environmental Chemistry, Organic chemistry, Exponential decay, ComputingMilieux_MISCELLANEOUS, Volatile Organic Compounds, Atmosphere, Temperature, Humidity, General Chemistry, Oxidants, Toluene, Aerosol, Chavicol, chemistry, [SDE]Environmental Sciences, Particle, Particulate Matter, Oxidation-Reduction, Mass fraction
Abstract

Secondary organic aerosol (SOA) is well-known to have adverse effects on air quality and human health. However, the dynamic mechanisms occurring during SOA formation and evolution are poorly understood. The time-resolved SOA composition formed during the photo-oxidation of three aromatic compounds, methyl chavicol, toluene and 4-methyl catechol, were investigated at the European Photoreactor. SOA was collected using a particle into liquid sampler and analyzed offline using state-of-the-art mass spectrometry to produce temporal profiles of individual photo-oxidation products. In the photo-oxidation of methyl chavicol, 70 individual compounds were characterized and three distinctive temporal profile shapes were observed. The calculated mass fraction (Ci,aer/COA) of the individual SOA compounds showed either a linear trend (increasing/decreasing) or exponential decay with time. Substituted nitrophenols showed an exponential decay, with the nitro-group on the aromatic ring found to control the formation and loss of these species in the aerosol phase. Nitrophenols from both methyl chavicol and toluene photo-oxidation experiments showed a strong relationship with the NO2/NO (ppbv/ppbv) ratio and were observed during initial SOA growth. The location of the nitrophenol aromatic substitutions was found to be critically important, with the nitrophenol in the photo-oxidation of 4-methyl catechol not partitioning into the aerosol phase until irradiation had stopped; highlighting the importance of studying SOA formation and evolution at a molecular level.

Published
2015

40. Atmospheric isoprene ozonolysis: impacts of stabilised Criegee intermediate reactions with SO2, H2O and dimethyl sulfide

Author

William J. Bloss, Luc Vereecken, Andrew R. Rickard, Mike J. Newland, Amalia Muñoz, and Milagros Ródenas

Subjects
Atmospheric Science, chemistry.chemical_compound, Ozone, Ozonolysis, Reaction rate constant, Chemistry, Criegee intermediate, Inorganic chemistry, Dimethyl sulfide, Photochemistry, Decomposition, Isoprene, NOx
Abstract

Isoprene is the dominant global biogenic volatile organic compound (VOC) emission. Reactions of isoprene with ozone are known to form stabilised Criegee intermediates (SCIs), which have recently been shown to be potentially important oxidants for SO2 and NO2 in the atmosphere; however the significance of this chemistry for SO2 processing (affecting sulfate aerosol) and NO2 processing (affecting NOx levels) depends critically upon the fate of the SCIs with respect to reaction with water and decomposition. Here, we have investigated the removal of SO2 in the presence of isoprene and ozone, as a function of humidity, under atmospheric boundary layer conditions. The SO2 removal displays a clear dependence on relative humidity, confirming a significant reaction for isoprene-derived SCIs with H2O. Under excess SO2 conditions, the total isoprene ozonolysis SCI yield was calculated to be 0.56 (±0.03). The observed SO2 removal kinetics are consistent with a relative rate constant, k(SCI + H2O) / k(SCI + SO2), of 3.1 (±0.5) × 10−5 for isoprene-derived SCIs. The relative rate constant for k(SCI decomposition) / k(SCI+SO2) is 3.0 (±3.2) × 1011 cm−3. Uncertainties are ±2σ and represent combined systematic and precision components. These kinetic parameters are based on the simplification that a single SCI species is formed in isoprene ozonolysis, an approximation which describes the results well across the full range of experimental conditions. Our data indicate that isoprene-derived SCIs are unlikely to make a substantial contribution to gas-phase SO2 oxidation in the troposphere. We also present results from an analogous set of experiments, which show a clear dependence of SO2 removal in the isoprene–ozone system as a function of dimethyl sulfide concentration. We propose that this behaviour arises from a rapid reaction between isoprene-derived SCIs and dimethyl sulfide (DMS); the observed SO2 removal kinetics are consistent with a relative rate constant, k(SCI + DMS) / k(SCI + SO2), of 3.5 (±1.8). This result suggests that SCIs may contribute to the oxidation of DMS in the atmosphere and that this process could therefore influence new particle formation in regions impacted by emissions of unsaturated hydrocarbons and DMS.

Published
2015

41. Instrument intercomparison of glyoxal, methyl glyoxal and NO2 under simulated atmospheric conditions

Author

M. J. S. Daniels, Salvatore Peppe, Frank N. Keutsch, Stephen M. Ball, S. B. Henry, J. Mak, Iain C. A. Goodall, L. Su, Eleanor M. Waxman, Milagros Ródenas, Andrew R. Rickard, M. T. Baeza-Romero, G. S. Tyndall, Amalia Muñoz, Teresa Vera, Sun Whe Kim, Rainer Volkamer, Esther Borrás, P. Sánchez, Roger Seco, Paul S. Monks, Mónica Vázquez, Thomas Karl, John J. Orlando, and Ryan Thalman

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Chemistry, Differential optical absorption spectroscopy, Analytical chemistry, 010501 environmental sciences, 01 natural sciences, 7. Clean energy, chemistry.chemical_compound, 13. Climate action, Glyoxal, Fourier transform infrared spectroscopy, Spectroscopy, Absorption (electromagnetic radiation), Isoprene, Proton-transfer-reaction mass spectrometry, NOx, 0105 earth and related environmental sciences
Abstract

The α-dicarbonyl compounds glyoxal (CHOCHO) and methyl glyoxal (CH3C(O)CHO) are produced in the atmosphere by the oxidation of hydrocarbons and emitted directly from pyrogenic sources. Measurements of ambient concentrations inform about the rate of hydrocarbon oxidation, oxidative capacity, and secondary organic aerosol (SOA) formation. We present results from a comprehensive instrument comparison effort at two simulation chamber facilities in the US and Europe that included nine instruments, and seven different measurement techniques: broadband cavity enhanced absorption spectroscopy (BBCEAS), cavity-enhanced differential optical absorption spectroscopy (CE-DOAS), white-cell DOAS, Fourier transform infrared spectroscopy (FTIR, two separate instruments), laser-induced phosphorescence (LIP), solid-phase micro extraction (SPME), and proton transfer reaction mass spectrometry (PTR-ToF-MS, two separate instruments; for methyl glyoxal only because no significant response was observed for glyoxal). Experiments at the National Center for Atmospheric Research (NCAR) compare three independent sources of calibration as a function of temperature (293–330 K). Calibrations from absorption cross-section spectra at UV-visible and IR wavelengths are found to agree within 2% for glyoxal, and 4% for methyl glyoxal at all temperatures; further calibrations based on ion–molecule rate constant calculations agreed within 5% for methyl glyoxal at all temperatures. At the European Photoreactor (EUPHORE) all measurements are calibrated from the same UV-visible spectra (either directly or indirectly), thus minimizing potential systematic bias. We find excellent linearity under idealized conditions (pure glyoxal or methyl glyoxal, R2 > 0.96), and in complex gas mixtures characteristic of dry photochemical smog systems (o-xylene/NOx and isoprene/NOx, R2 > 0.95; R2 ∼ 0.65 for offline SPME measurements of methyl glyoxal). The correlations are more variable in humid ambient air mixtures (RH > 45%) for methyl glyoxal (0.58 < R2 < 0.68) than for glyoxal (0.79 < R2 < 0.99). The intercepts of correlations were insignificant for the most part (below the instruments' experimentally determined detection limits); slopes further varied by less than 5% for instruments that could also simultaneously measure NO2. For glyoxal and methyl glyoxal the slopes varied by less than 12 and 17% (both 3-σ) between direct absorption techniques (i.e., calibration from knowledge of the absorption cross section). We find a larger variability among in situ techniques that employ external calibration sources (75–90%, 3-σ), and/or techniques that employ offline analysis. Our intercomparison reveals existing differences in reports about precision and detection limits in the literature, and enables comparison on a common basis by observing a common air mass. Finally, we evaluate the influence of interfering species (e.g., NO2, O3 and H2O) of relevance in field and laboratory applications. Techniques now exist to conduct fast and accurate measurements of glyoxal at ambient concentrations, and methyl glyoxal under simulated conditions. However, techniques to measure methyl glyoxal at ambient concentrations remain a challenge, and would be desirable.

Published
2015

42. Theoretical study of the reactions of Criegee intermediates with ozone, alkylhydroperoxides, and carbon monoxide

Author

William J. Bloss, Mike J. Newland, Luc Vereecken, and Andrew R. Rickard

Subjects
chemistry.chemical_compound, Ozone, chemistry, Insertion reaction, General Physics and Astronomy, Organic chemistry, Molecule, Ether, Physical and Theoretical Chemistry, Photochemistry, Carbon monoxide
Abstract

The reaction of Criegee intermediates (CI) with ozone, O3, has been re-examined with higher levels of theory, following earlier reports that O3 could be a relevant sink of CI. The updated rate coefficients indicate that the reaction is somewhat slower than originally anticipated, and is not expected to play a role in the troposphere. In experimental (laboratory) conditions, the CI + O3 reaction can be important. The reaction of CI with ROOH intermediates is found to proceed through a pre-reactive complex, and the insertion process allows for the formation of oligomers in agreement with recent experimental observations. The CI + ROOH reaction also allows for the formation of ether oxides, which don't react with H2O but can oxidize SO2. Under tropospheric conditions, the ether oxides are expected to re-dissociate to the CI + ROOH complex, and ultimately follow the insertion reaction forming a longer-chain hydroperoxide. The CI + ROOH reaction is not expected to play a significant role in the atmosphere. The reaction of CI with CO molecules was studied at very high levels of theory, but no energetically viable route was found, leading to very low rate coefficients. These results are compared against an extensive literature overview of experimental data.

Published
2015

44. A self-consistent, multi-variate method for the determination of gas phase rate coefficients, applied to reactions of atmospheric VOCs and the hydroxyl radical

Author

Jacob T. Shaw, Richard T. Lidster, Danny R. Cryer, Noelia Ramirez, Graham A. Boustead, Lisa K. Whalley, Trevor Ingham, Andrew R. Rickard, Rachel E. Dunmore, Dwayne E. Heard, Ally C. Lewis, Lucy J. Carpenter, Jacqui F. Hamilton, and Terry J. Dillon

Subjects
13. Climate action
Abstract

Gas-phase rate coefficients are fundamental to understanding atmospheric chemistry, yet experimental data are not available for the oxidation reactions of many of the thousands of volatile organic compounds (VOCs) observed in the troposphere. Here a new experimental method is reported for the simultaneous study of reactions between multiple different VOCs and OH, the most important daytime atmospheric radical oxidant. This technique is based upon established relative rate concepts but has the advantage of a much higher throughput of target VOCs. By evaluating multiple VOCs in each experiment, and through measurement of the depletion in each VOC after reaction with OH, the OH + VOC reaction rate coefficients can be derived. Results from experiments conducted under controlled laboratory conditions were in good agreement with the available literature for the reaction of nineteen VOCs, prepared in synthetic gas mixtures, with OH. This approach was used to determine a rate coefficient for the reaction of OH with 2,3-dimethylpent-1-ene for the first time; k = 5.7 (&pm;0.3) × 10–11–cm3 molecule−1 s−1. In addition, a further seven VOCs had only two, or fewer, individual OH rate coefficient measurements available in the literature. The results from this work were in good agreement with those measurements. A similar dataset, at an elevated temperature of 323 (±10) K, was used to determine new OH rate coefficients for twelve aromatic, five alkane, five alkene and three monoterpene VOC + OH reactions. In OH relative reactivity experiments that used ambient air at the University of York, a large number of different VOCs were observed, of which 23 were positively identified. 19 OH rate coefficients were derived from these ambient air samples, including ten reactions for which data was previously unavailable at the elevated reaction temperature of T = 323 (±10) K.

Published
2017

45. Elucidating the fate of the OH-adduct in toluene oxidation under tropospheric boundary layer conditions

Author

Mike J. Newland, Andrew R. Rickard, and Michael E. Jenkin

Subjects
Multidisciplinary, 010504 meteorology & atmospheric sciences, Methylglyoxal, 010402 general chemistry, 01 natural sciences, Toluene, Toluene oxidation, 0104 chemical sciences, Adduct, chemistry.chemical_compound, Boundary layer, chemistry, Computational chemistry, Yield (chemistry), Atmospheric chemistry, Organic chemistry, Glyoxal, 0105 earth and related environmental sciences
Abstract

Ji et al. (1) published a study examining the mechanism of the initial stages of OH-initiated oxidation of toluene. Their results challenge the mechanisms used in atmospheric chemistry models [e.g., Master Chemical Mechanism (MCM) (2)] derived from chamber experiments at atmospheric conditions, and previous experimental (3, 4) and theoretical studies (5, 6). In these mechanisms, the main product (55–65%) of the O2 reaction with the OH-adduct is a peroxy-peroxide bridged radical ( cyc-RO 2 , Scheme 1), the subsequent chemistry of which goes on to yield dienals and the dicarbonyls: glyoxal and methylglyoxal. The present study detected a negligible yield of these dicarbonyl products. From this, the authors conclude that the cyc-RO 2 pathway is insignificant under atmospheric conditions. Scheme 1. Simplified representation of chemical mechanism of OH-initiated toluene oxidation. For clarity, … [↵][1]1To whom correspondence should be addressed. Email: mike.newland{at}york.ac.uk. [1]: #xref-corresp-1-1

Published
2017

47. New tools for atmospheric chemistry: general discussion

Author

Steven S. Brown, Roderic L. Jones, A. R. Ravishankara, Peter A. Alpert, Craig A. Taatjes, Gabriel Isaacman-VanWertz, Timothy J. Wallington, Jing Dou, Andreas Wahner, Stephen Arnold, Jonathan P. Reid, Aleksandra Marsh, Andrew R. Rickard, Yinon Rudich, Andreas Petzold, Meredith G. Hastings, Andrew Grantham, Jos Lelieveld, Alla Zelenyuk, Jacinta Edebeli, Adam R. Vaughan, Grazia Rovelli, Paul Young, Hugh Coe, William C. Porter, Markus Kalberer, Barbara J. Finlayson-Pitts, Steven C. Campbell, Sarah Moller, Dwayne E. Heard, Astrid Kiendler-Scharr, Alastair C. Lewis, Kirsti Ashworth, Jacqueline F. Hamilton, Jonathan Williams, Alexander T. Archibald, Daniel A. Knopf, Lucy J. Carpenter, Eloise A. Marais, and Jesse H. Kroll

Subjects
Atmospheric chemistry, Environmental science, Physical and Theoretical Chemistry, Atmospheric sciences
Published
2017

48. A case study of aerosol scavenging in a biomass burning plume over eastern Canada during the 2011 BORTAS field experiment

Author

L. Dan, A. C. Lewis, James Allan, Kaley A. Walker, Jeffrey R. Pierce, James D. Lee, Debora Griffin, Thomas J. Duck, Mark D. Gibson, J. Kliever, Jonathan Taylor, Kimiko M. Sakamoto, Mark Parrington, J. E. Franklin, Auromeet Saha, Paul I. Palmer, Jason Hopper, Yann Blanchard, Andrew R. Rickard, Hugh Coe, James R. Drummond, Glen Lesins, Lucy Chisholm, K. R. Curry, and D. L. Waugh

Subjects
Atmospheric Science, execution, design, optical depth, lcsh:Chemistry, Troposphere, instrument, Scavenging, Optical depth, Smoke, model, Taiga, lcsh:QC1-999, Aerosol, Plume, Trace gas, co, lcsh:QD1-999, Climatology, network, impact, Environmental science, spectrometer, aircraft, lcsh:Physics
Abstract

We present measurements of a long-range smoke transport event recorded on 20–21 July 2011 over Halifax, Nova Scotia, Canada, during the Quantifying the impact of BOReal forest fires on Tropospheric oxidants over the Atlantic using Aircraft and Satellites (BORTAS-B) campaign. Ground-based Fourier transform spectrometers and photometers detected air masses associated with large wildland fires burning in eastern Manitoba and western Ontario. We investigate a plume with high trace gas amounts but low amounts of particles that preceded and overlapped at the Halifax site with a second plume with high trace gas loadings and significant amounts of particulate material. We show that the first plume experienced a meteorological scavenging event, but the second plume had not been similarly scavenged. This points to the necessity to account carefully for the plume history when considering long-range transport since simultaneous or near-simultaneous times of arrival are not necessarily indicative of either similar trajectories or meteorological history. We investigate the origin of the scavenged plume, and the possibility of an aerosol wet deposition event occurring in the plume ~ 24 h prior to the measurements over Halifax. The region of lofting and scavenging is only monitored on an intermittent basis by the present observing network, and thus we must consider many different pieces of evidence in an effort to understand the early dynamics of the plume. Through this discussion we also demonstrate the value of having many simultaneous remote-sensing measurements in order to understand the physical and chemical behaviour of biomass burning plumes.

Published
2014

49. Radical Product Yields from the Ozonolysis of Short Chain Alkenes under Atmospheric Boundary Layer Conditions

Author

Timo Carr, Paul S. Monks, Karen E. Hornsby, William J. Bloss, Marie Camredon, Andrew R. Rickard, M. S. Alam, and Kevin Wyche

Subjects
chemistry.chemical_classification, Ozonolysis, Ozone, Molecular Structure, Atmosphere, Hydroxyl Radical, Alkene, Planetary boundary layer, Radical, Alkenes, Photochemistry, Fluorescence, Peroxides, Propene, chemistry.chemical_compound, chemistry, Physical and Theoretical Chemistry, Isoprene
Abstract

The gas-phase reaction of ozone with unsaturated volatile organic compounds (VOCs), alkenes, is an important source of the critical atmospheric oxidant OH, especially at night when other photolytic radical initiation routes cannot occur. Alkene ozonolysis is also known to directly form HO2 radicals, which may be readily converted to OH through reaction with NO, but whose formation is poorly understood. We report a study of the radical (OH, HO2, and RO2) production from a series of small alkenes (propene, 1-butene, cis-2-butene, trans-2-butene, 2-methylpropene, 2,3-dimethyl-2-butene (tetramethyl ethene, TME), and isoprene). Experiments were performed in the European Photoreactor (EUPHORE) atmospheric simulation chamber, with OH and HO2 levels directly measured by laser-induced fluorescence (LIF) and HO2 + ΣRO2 levels measured by peroxy-radical chemical amplification (PERCA). OH yields were found to be in good agreement with the majority of previous studies performed under comparable conditions (atmospheric pressure, long time scales) using tracer and scavenger approaches. HO2 yields ranged from 4% (trans-2-butene) to 34% (2-methylpropene), lower than previous experimental determinations. Increasing humidity further reduced the HO2 yields obtained, by typically 50% for an RH increase from 0.5 to 30%, suggesting that HOx production from alkene ozonolysis may be lower than current models suggest under (humid) ambient atmospheric boundary layer conditions. The mechanistic origin of the OH and HO2 production observed is discussed in the context of previous experimental and theoretical studies.

Published
2013

50. Predictive utility of cardiac ultrasound in traumatic cardiac arrest in a combat casualty

Author

Rex Kinnear-Mellor, R Rickard, K Newton, and T Woolley

Subjects
Adult, Male, Resuscitation, Traumatic cardiac arrest, 030204 cardiovascular system & hematology, Return of spontaneous circulation, Cardiac Ultrasound, Young Adult, 03 medical and health sciences, Fatal Outcome, 0302 clinical medicine, Amputation, Traumatic, Blast Injuries, medicine, Humans, Asystole, business.industry, Ultrasound, Afghanistan, 030208 emergency & critical care medicine, General Medicine, Combat casualty, medicine.disease, Heart Arrest, Thrombelastography, Military Personnel, Echocardiography, Anesthesia, cardiovascular system, Ultrasonography, business
Abstract

We report a case of traumatic cardiac arrest in a combat casualty who was resuscitated to return of spontaneous circulation despite asystole and no visible cardiac activity on initial ultrasound examination. This return of spontaneous circulation suggests that survival may be possible in traumatic cardiac arrest due to exsanguination, even when there is no demonstrable cardiac activity on ultrasound. Cardiac ultrasonography was performed for 10 s only. We suggest that cardiac ultrasonography should be performed for a minimum of 1 min during volume resuscitation. If absence of cardiac activity is confirmed once the heart is full, and there are no other signs of life (including pupillary reaction), then termination of resuscitation should be considered.

Published
2015

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