Your search keyword '"Sina Hackenberg"' showing total 6 results

1. Supplementary material to 'Observations and modelling of glyoxal in the tropical Atlantic marine boundary layer'

Author

Hannah Walker, Daniel Stone, Trevor Ingham, Sina Hackenberg, Danny Cryer, Shalini Punjabi, Katie Read, James Lee, Lisa Whalley, Dominick Vincent Spracklen, Lucy Jane Carpenter, Steve Robert Arnold, and Dwayne Ellis Heard

Published

2021

2. Observations and modelling of glyoxal in the tropical Atlantic marine boundary layer

Author

Daniel Stone, Steve R. Arnold, D. R. Cryer, Lisa K. Whalley, Trevor Ingham, James D. Lee, Dominick V. Spracklen, Dwayne E. Heard, Hannah Walker, Sina Hackenberg, Shalini Punjabi, Lucy J. Carpenter, and Katie A. Read

Subjects

chemistry.chemical_classification, Cape verde, Atmospheric Science, chemistry.chemical_compound, Deposition (aerosol physics), Acetylene, chemistry, Base (chemistry), Analytical chemistry, Acetaldehyde, Mixing ratio, Glyoxal, Aerosol

Abstract

In situ field measurements of glyoxal at the surface in the tropical marine boundary layer have been made with a temporal resolution of a few minutes during two 4-week campaigns in June–July and August–September 2014 at the Cape Verde Atmospheric Observatory (CVAO; 16∘52′ N, 24∘52′ W). Using laser-induced phosphorescence spectroscopy with an instrumental detection limit of ∼1 pptv (1 h averaging), volume mixing ratios up to ∼10 pptv were observed, with 24 h averaged mixing ratios of 4.9 and 6.3 pptv observed during the first and second campaigns, respectively. Some diel behaviour was observed, but this was not marked. A box model using the detailed Master Chemical Mechanism (version 3.2) and constrained with detailed observations of a suite of species co-measured at the observatory was used to calculate glyoxal mixing ratios. There is a general model underestimation of the glyoxal observations during both campaigns, with mean midday (11:00–13:00) observed-to-modelled ratios for glyoxal of 3.2 and 4.2 for the two campaigns, respectively, and higher ratios at night. A rate of production analysis shows the dominant sources of glyoxal in this environment to be the reactions of OH with glycolaldehyde and acetylene, with a significant contribution from the reaction of OH with the peroxide HC(O)CH2OOH, which itself derives from OH oxidation of acetaldehyde. Increased mixing ratios of acetaldehyde, which is unconstrained and potentially underestimated in the base model, can significantly improve the agreement between the observed and modelled glyoxal during the day. Mean midday observed-to-modelled glyoxal ratios decreased to 1.3 and 1.8 for campaigns 1 and 2, respectively, on constraint to a fixed acetaldehyde mixing ratio of 200 pptv, which is consistent with recent airborne measurements near CVAO. However, a significant model under-prediction remains at night. The model showed limited sensitivity to changes in deposition rates of model intermediates and the uptake of glyoxal onto aerosol compared with sensitivity to uncertainties in chemical precursors. The midday (11:00–13:00) mean modelled glyoxal mixing ratio decreased by factors of 0.87 and 0.90 on doubling the deposition rates of model intermediates and aerosol uptake of glyoxal, respectively, and increased by factors of 1.10 and 1.06 on halving the deposition rates of model intermediates and aerosol uptake of glyoxal, respectively. Although measured levels of monoterpenes at the site (total of ∼1 pptv) do not significantly influence the model calculated levels of glyoxal, transport of air from a source region with high monoterpene emissions to the site has the potential to give elevated mixing ratios of glyoxal from monoterpene oxidation products, but the values are highly sensitive to the deposition rates of these oxidised intermediates. A source of glyoxal derived from production in the ocean surface organic microlayer cannot be ruled out on the basis of this work and may be significant at night.

Published

2021

3. A synthesis inversion to constrain global emissions of two very short lived chlorocarbons:Dichloromethane, and Perchloroethylene

Author

Tanja Schuck, David Sherry, David E. Oram, Chris Wilson, Stephen J. Andrews, Martin K. Vollmer, Michela Maione, Tom Claxton, Oliver Wild, Chris Rene Lunder, Mi Kyung Park, Sue M. Schauffler, Martyn P. Chipperfield, Yoko Yokouchi, Ryan Hossaini, Jgor Arduini, Paul B. Krummel, Jens Mühle, Maria A. Navarro, Takuya Saito, Elliot Atlas, Lucy J. Carpenter, Sunyoung Park, Stephen A. Montzka, Ewa Bednarz, Simon O'Doherty, Andreas Engel, Dickon Young, and Sina Hackenberg

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Chemical transport model, vsls, emissions, Atmospheric sciences, 01 natural sciences, Ozone depletion, dichloromethane, Troposphere, inversion, chemistry.chemical_compound, Geophysics, perchloroethylene, chemistry, Space and Planetary Science, Montreal Protocol, Earth and Planetary Sciences (miscellaneous), Environmental science, montreal protocol, 0105 earth and related environmental sciences, Dichloromethane

Abstract

Dichloromethane (CH2Cl2) and perchloroethylene (C2Cl4) are chlorinated very short lived substances (Cl-VSLS) with anthropogenic sources. Recent studies highlight the increasing influence of such compounds, particularly CH2Cl2, on the stratospheric chlorine budget and therefore on ozone depletion. Here, a multiyear global-scale synthesis inversion was performed to optimize CH2Cl2 (2006–2017) and C2Cl4 (2007–2017) emissions. The approach combines long-term surface observations from global monitoring networks, output from a three-dimensional chemical transport model (TOMCAT), and novel bottom-up information on prior industry emissions. Our posterior results show an increase in global CH2Cl2 emissions from 637 ± 36 Gg yr−1 in 2006 to 1,171 ± 45 Gg yr−1 in 2017, with Asian emissions accounting for 68% and 89% of these totals, respectively. In absolute terms, Asian CH2Cl2 emissions increased annually by 51 Gg yr−1 over the study period, while European and North American emissions declined, indicating a continental-scale shift in emission distribution since the mid-2000s. For C2Cl4, we estimate a decrease in global emissions from 141 ± 14 Gg yr−1 in 2007 to 106 ± 12 Gg yr−1 in 2017. The time-varying posterior emissions offer significant improvements over the prior. Utilizing the posterior emissions leads to modeled tropospheric CH2Cl2 and C2Cl4 abundances and trends in good agreement to those observed (including independent observations to the inversion). A shorter C2Cl4 lifetime, from including an uncertain Cl sink, leads to larger global C2Cl4 emissions by a factor of ~1.5, which in some places improves model-measurement agreement. The sensitivity of our findings to assumptions in the inversion procedure, including CH2Cl2 oceanic emissions, is discussed.

Published

2020

4. Evaluating Oceanic Uptake of Atmospheric CCl 4 : A Combined Analysis of Model Simulations and Observations

Author

James H. Butler, Sina Hackenberg, Erik T. Buitenhuis, Stephen J. Andrews, Marie-José Messias, Lucy J. Carpenter, and Parvadha Suntharalingam

Subjects

Geophysics, 010504 meteorology & atmospheric sciences, 13. Climate action, Range (statistics), General Earth and Planetary Sciences, Flux, Environmental science, Biogeochemistry, 14. Life underwater, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, 0105 earth and related environmental sciences

Abstract

We provide new estimates of the air‐sea flux of CCl4 using simulations from a global ocean biogeochemistry model (NEMO‐PlankTOM) in combination with depth‐resolved CCl4 observations from global oceanic databases. Estimates of global oceanic CCl4 uptake are derived from a range of model analyses, including prescribed parameterizations using reported values on hydrolysis and degradation, and analyses optimized using the global observational databases. We evaluate the sensitivity of our results to uncertainties in air‐sea gas exchange parameterization, estimation period, and circulation processes. Our best constrained estimate of ocean CCl4 uptake for the period 1996–2000 is 20.1 Gg/year (range 16.6–22.7), corresponding to estimates of the partial atmospheric lifetime with respect to ocean uptake of 124 (110–150) years. This new oceanic lifetime implies higher emissions of CCl4 than currently estimated and therefore a larger missing atmospheric source of CCl4.

Published

2019

5. Technical Note: A fully automated purge and trap GC-MS system for quantification of volatile organic compound (VOC) fluxes between the ocean and atmosphere

Author

Lucy J. Carpenter, Stephen J. Andrews, and Sina Hackenberg

Subjects

chemistry.chemical_classification, lcsh:GE1-350, Meteorology, Thermal desorption, lcsh:Geography. Anthropology. Recreation, Trace gas, Atmosphere, Boiling point, chemistry, lcsh:G, Environmental chemistry, Environmental science, Seawater, Volatile organic compound, Gas chromatography–mass spectrometry, Water vapor, lcsh:Environmental sciences

Abstract

The oceans are a key source of a number of atmospherically important volatile gases. The accurate and robust determination of trace gases in seawater is a significant analytical challenge, requiring reproducible and ideally automated sample handling, a high efficiency of seawater–air transfer, removal of water vapour from the sample stream, and high sensitivity and selectivity of the analysis. Here we describe a system that was developed for the fully automated analysis of dissolved very short-lived halogenated species (VSLS) sampled from an under-way seawater supply. The system can also be used for semi-automated batch sampling from Niskin bottles filled during CTD (conductivity, temperature, depth) profiles. The essential components comprise a bespoke, automated purge and trap (AutoP & T) unit coupled to a commercial thermal desorption and gas chromatograph mass spectrometer (TD-GC-MS). The AutoP & T system has completed five research cruises, from the tropics to the poles, and collected over 2500 oceanic samples to date. It is able to quantify >25 species over a boiling point range of 34–180 °C with Henry's law coefficients of 0.018 and greater (CH22l, kHcc dimensionless gas/aqueous) and has been used to measure organic sulfurs, hydrocarbons, halocarbons and terpenes. In the eastern tropical Pacific, the high sensitivity and sampling frequency provided new information regarding the distribution of VSLS, including novel measurements of a photolytically driven diurnal cycle of CH22l within the surface ocean water.

Published

2015

6. Basin-scale observations of monoterpenes in the Arctic and Atlantic Oceans

Author

Lucy J. Carpenter, Gavin H. Tilstone, Alastair C. Lewis, Alison Small, Kristen M. Reifel, Steve R. Arnold, Heather A. Bouman, Ruth L. Airs, D.G. Cummings, Jamie K. Minaeian, Stephen J. Andrews, Glen A. Tarran, and Sina Hackenberg

Subjects

010504 meteorology & atmospheric sciences, Arctic Regions, Monoterpene, General Chemistry, 010501 environmental sciences, Atmospheric sciences, 01 natural sciences, Global model, The arctic, Ocimene, Bridged Bicyclo Compounds, chemistry.chemical_compound, chemistry, Myrcene, Climatology, Monoterpenes, Environmental Chemistry, Seawater, Atlantic Ocean, Basin scale, Environmental Monitoring, 0105 earth and related environmental sciences

Abstract

We report novel in situ speciated observations of monoterpenes (α- and β-pinene, myrcene, δ3-carene, ocimene, limonene) in seawater and air during three cruises in the Arctic and Atlantic Oceans, in/over generally oligotrophic waters. Oceanic concentrations of the individual monoterpenes ranged from below the detection limit of

Published

2017