A coupled model of the global cycles of carbonyl sulfide and CO<sub>2</sub>: A possible new window on the carbon cycle

Berry, J. A.; Wolf, Adam; Campbell, J. Elliott; Baker, Ian; Blake, N. J.; Blake, D. R.; Denning, A. S.; Kawa, S. R.; Montzka, S. A.; Seibt, Ulrike; Stimler, Keren; Yakir, Dan; Zhu, Zhenfeng

doi:10.1002/jgrg.20068

Cited by 194 publications

(541 citation statements)

References 55 publications

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“…A monthly mean of TES OCS results from June 2006 was published in Kuai et al (2015), which further validated the concept that direct ocean emissions of OCS are much greater than previously thought (Berry et al, 2013). The published data included retrievals over the ocean around ±40…”

Section: Previous Estimates From Satellitesupporting

confidence: 57%

“…Ingestion of OCS via leaf uptake only goes one way, meaning, plants do not respire OCS as they do unused CO 2 . Since OCS is roughly 4 times more variable than CO 2 , Berry et al (2013) suggested that remote detection of OCS could be used as a proxy towards estimating CO 2 fluxes over areas of dense vegetation. The remaining portion of the OCS sink budget is atmospheric loss due to reaction with the OH − and O − radicals along with stratospheric photolysis (Kettle et al, 2002).…”

Section: Sources and Sinksmentioning

confidence: 99%

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Fast retrievals of tropospheric carbonyl sulfide with IASI

Vincent

Dudhia

2017

Atmos. Chem. Phys.

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Abstract. Iterative retrievals of trace gases, such as carbonyl sulfide (OCS), from satellites can be exceedingly slow. The algorithm may even fail to keep pace with data acquisition such that analysis is limited to local events of special interest and short time spans. With this in mind, a linear retrieval scheme was developed to estimate total column amounts of OCS at a rate roughly 10 4 times faster than a typical iterative retrieval. This scheme incorporates two concepts not utilized in previously published linear estimates. First, all physical parameters affecting the signal are included in the state vector and accounted for jointly, rather than treated as effective noise. Second, the initialization point is determined from an ensemble of atmospheres based on comparing the model spectra to the observations, thus improving the linearity of the problem. All of the 2014 data from the Infrared Atmospheric Sounding Interferometer (IASI), instruments A and B, were analysed and showed spatial features of OCS total columns, including depletions over tropical rainforests, seasonal enhancements over the oceans, and distinct OCS features over land. Error due to assuming linearity was found to be on the order of 11 % globally for OCS. However, systematic errors from effects such as varying surface emissivity and extinction due to aerosols have yet to be robustly characterized. Comparisons to surface volume mixing ratio in situ samples taken by NOAA show seasonal correlations greater than 0.7 for five out of seven sites across the globe. Furthermore, this linear scheme was applied to OCS, but may also be used as a rapid estimator of any detectable trace gas using IASI or similar nadir-viewing instruments.

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Section: Previous Estimates From Satellitesupporting

confidence: 57%

Section: Sources and Sinksmentioning

confidence: 99%

Fast retrievals of tropospheric carbonyl sulfide with IASI

Vincent

Dudhia

2017

Atmos. Chem. Phys.

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“…It has a greenhouse gas effect based on absorption of far-infrared radiation (Brühl et al, 2012). OCS is also found as a potential trace gas, other than carbon dioxide, that could provide independent information about carbon cycle processes (Montzka et al, 2007;Campbell et al, 2008;Suntharalingam et al, 2008;Wohlfahrt et al, 2012;Blonquist et al, 2011;Berry et al, 2013). For example, recent work by Campbell et al (2008) suggests that carbonyl sulfide is a good photosynthetic tracer.…”

Section: Introductionmentioning

confidence: 99%

Characterization of Aura TES carbonyl sulfide retrievals over ocean

et al. 2014

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Abstract. We present a description of the NASA Aura Tropospheric Emission Spectrometer (TES) carbonyl sulfide (OCS) retrieval algorithm for oceanic observations, along with evaluation of the biases and uncertainties using aircraft profiles from the HIPPO (HIAPER Pole-to-Pole Observations) campaign and data from the NOAA Mauna Loa site. In general, the OCS retrievals (1) have less than 1.0 degree of freedom for signals (DOFs), (2) are sensitive in the mid-troposphere with a peak sensitivity typically between 300 and 500 hPa, (3) but have much smaller systematic errors from temperature, CO 2 and H 2 O calibrations relative to random errors from measurement noise. We estimate the monthly means from TES measurements averaged over multiple years so that random errors are reduced and useful information about OCS seasonal and latitudinal variability can be derived. With this averaging, TES OCS data are found to be consistent (within the calculated uncertainties) with NOAA ground observations and HIPPO aircraft measurements. TES OCS data also captures the seasonal and latitudinal variations observed by these in situ data.

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“…Studies considering the large-scale atmospheric variability of OCS have linked OCS fluxes and the photosynthetic uptake of CO 2 for regional and global scales (1,4,13). Leaf-scale studies have confirmed the OCS link to photosynthesis (14,15).…”

mentioning

confidence: 97%

“…7 and 8). The terrestrial biosphere is the largest sink for OCS (1,4,9,10) with uptake by both oxic soils (e.g., ref. 11) and vegetation (e.g., ref.…”

mentioning

confidence: 99%

Seasonal fluxes of carbonyl sulfide in a midlatitude forest

Commane

Meredith

Baker

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Carbonyl sulfide (OCS), the most abundant sulfur gas in the atmosphere, has a summer minimum associated with uptake by vegetation and soils, closely correlated with CO 2 . We report the first direct measurements to our knowledge of the ecosystem flux of OCS throughout an annual cycle, at a mixed temperate forest. The forest took up OCS during most of the growing season with an overall uptake of 1.36 ± 0.01 mol OCS per ha (43.5 ± 0.5 g S per ha, 95% confidence intervals) for the year. Daytime fluxes accounted for 72% of total uptake. Both soils and incompletely closed stomata in the canopy contributed to nighttime fluxes. Unexpected net OCS emission occurred during the warmest weeks in summer. Many requirements necessary to use fluxes of OCS as a simple estimate of photosynthesis were not met because OCS fluxes did not have a constant relationship with photosynthesis throughout an entire day or over the entire year. However, OCS fluxes provide a direct measure of ecosystem-scale stomatal conductance and mesophyll function, without relying on measures of soil evaporation or leaf temperature, and reveal previously unseen heterogeneity of forest canopy processes. Observations of OCS flux provide powerful, independent means to test and refine land surface and carbon cycle models at the ecosystem scale.carbonyl sulfide | carbon cycle | sulfur cycle | stomatal conductance C arbonyl sulfide (OCS) is the most abundant sulfur gas in the atmosphere (1), and biogeochemical cycling of OCS affects both the stratosphere and the troposphere. The tropospheric OCS mixing ratio is between 300 and 550 parts per trillion (ppt) (1) (10 −12 mol OCS per mol dry air), decreasing sharply with altitude in the stratosphere (2). In times of low volcanic activity, the sulfur budget and aerosol loading of the stratosphere are largely controlled by transport and photooxidation of OCS from the troposphere (3). The processes regulating emission and uptake of OCS are thus important factors in determining how changes in climate and land cover may affect the stratospheric sulfate layer.Oceans are the dominant source of atmospheric OCS (4), with smaller emissions from anthropogenic and terrestrial sources, such as wetlands and anoxic soils (e.g., refs. 5 and 6) and oxic soils during times of heat or drought stress (e.g., refs. 7 and 8). The terrestrial biosphere is the largest sink for OCS (1, 4, 9, 10) with uptake by both oxic soils (e.g., ref. 11) and vegetation (e.g., ref. 9). Once OCS molecules pass through the stomata of leaves, the uptake rate of OCS is controlled by reaction with carbonic anhydrase (CA) within the mesophyll, to produce H 2 S and CO 2 . CA is the same enzyme that hydrolyzes carbon dioxide (CO 2 ) in the first chemical step of photosynthesis (12).Studies considering the large-scale atmospheric variability of OCS have linked OCS fluxes and the photosynthetic uptake of CO 2 for regional and global scales (1, 4, 13). Leaf-scale studies have confirmed the OCS link to photosynthesis (14, 15). Initial OCS ecosystem flux estimations w...

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A coupled model of the global cycles of carbonyl sulfide and CO₂: A possible new window on the carbon cycle

Cited by 194 publications

References 55 publications

Fast retrievals of tropospheric carbonyl sulfide with IASI

Fast retrievals of tropospheric carbonyl sulfide with IASI

Characterization of Aura TES carbonyl sulfide retrievals over ocean

Seasonal fluxes of carbonyl sulfide in a midlatitude forest

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A coupled model of the global cycles of carbonyl sulfide and CO2: A possible new window on the carbon cycle

Cited by 194 publications

References 55 publications

Fast retrievals of tropospheric carbonyl sulfide with IASI

Fast retrievals of tropospheric carbonyl sulfide with IASI

Characterization of Aura TES carbonyl sulfide retrievals over ocean

Seasonal fluxes of carbonyl sulfide in a midlatitude forest

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Product

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A coupled model of the global cycles of carbonyl sulfide and CO₂: A possible new window on the carbon cycle