3 research outputs found
Atmospheric isoprene measurements reveal larger-than-expected Southern Ocean emissions
Isoprene is a key trace component of the atmosphere emitted by vegetation and other organisms. It is highly reactive and can impact atmospheric composition and climate by affecting the greenhouse gases ozone and methane and secondary organic aerosol formation. Marine fluxes are poorly constrained due to the paucity of long-term measurements; this in turn limits our understanding of isoprene cycling in the ocean. Here we present the analysis of isoprene concentrations in the atmosphere measured across the Southern Ocean over 4 months in the summertime. Some of the highest concentrations ( >500 ppt) originated from the marginal ice zone in the Ross and Amundsen seas, indicating the marginal ice zone is a significant source of isoprene at high latitudes. Using the United Kingdom Earth System Model we show that current estimates of sea-to-air isoprene fluxes underestimate observed isoprene by a factor >20. A daytime source of isoprene is required to reconcile models with observations. The model presented here suggests such an increase in isoprene emissions would lead to >8% decrease in the hydroxyl radical in regions of the Southern Ocean, with implications for our understanding of atmospheric oxidation and composition in remote environments, often used as proxies for the pre-industrial atmosphere
Atmospheric isoprene measurements reveal larger-than-expected Southern Ocean emissions
Isoprene is a key trace component of the atmosphere emitted by vegetation and other organisms. It is highly reactive and can impact atmospheric composition and climate by affecting the greenhouse gases ozone and methane and secondary organic aerosol formation. Marine fluxes are poorly constrained due to the paucity of long-term measurements; this in turn limits our understanding of isoprene cycling in the ocean. Here we present the analysis of isoprene concentrations in the atmosphere measured across the Southern Ocean over 4 months in the summertime. Some of the highest concentrations ( >500 ppt) originated from the marginal ice zone in the Ross and Amundsen seas, indicating the marginal ice zone is a significant source of isoprene at high latitudes. Using the United Kingdom Earth System Model we show that current estimates of sea-to-air isoprene fluxes underestimate observed isoprene by a factor >20. A daytime source of isoprene is required to reconcile models with observations. The model presented here suggests such an increase in isoprene emissions would lead to >8% decrease in the hydroxyl radical in regions of the Southern Ocean, with implications for our understanding of atmospheric oxidation and composition in remote environments, often used as proxies for the pre-industrial atmosphere.V.F. and N.R.P.H. were supported in the analysis of the data by UKRI NERC project Southern Ocean Clouds (NE/T006366/1)
Exploring the coupled ocean and atmosphere system with a data science approach applied to observations from the Antarctic Circumnavigation Expedition
The Southern Ocean is a critical component of Earth’s climate system, but its remoteness makes it
challenging to develop a holistic understanding of its processes from the small scale to the large scale. As a
result, our knowledge of this vast region remains largely incomplete. The Antarctic Circumnavigation Expedi�tion (ACE, austral summer 2016/2017) surveyed a large number of variables describing the state of the ocean
and the atmosphere, the freshwater cycle, atmospheric chemistry, and ocean biogeochemistry and microbiology.
This circumpolar cruise included visits to 12 remote islands, the marginal ice zone, and the Antarctic coast.
Here, we use 111 of the observed variables to study the latitudinal gradients, seasonality, shorter-term variations,
geographic setting of environmental processes, and interactions between them over the duration of 90 d. To re�duce the dimensionality and complexity of the dataset and make the relations between variables interpretable
we applied an unsupervised machine learning method, the sparse principal component analysis (sPCA), which
describes environmental processes through 14 latent variables. To derive a robust statistical perspective on these
processes and to estimate the uncertainty in the sPCA decomposition, we have developed a bootstrap approach.
Our results provide a proof of concept that sPCA with uncertainty analysis is able to identify temporal patterns
from diurnal to seasonal cycles, as well as geographical gradients and “hotspots” of interaction between envi�ronmental compartments. While confirming many well known processes, our analysis provides novel insights
into the Southern Ocean water cycle (freshwater fluxes), trace gases (interplay between seasonality, sources, and
sinks), and microbial communities (nutrient limitation and island mass effects at the largest scale ever reported).
More specifically, we identify the important role of the oceanic circulations, frontal zones, and islands in shap�ing the nutrient availability that controls biological community composition and productivity; the fact that sea
ice controls sea water salinity, dampens the wave field, and is associated with increased phytoplankton growth
and net community productivity possibly due to iron fertilisation and reduced light limitation; and the clear
regional patterns of aerosol characteristics that have emerged, stressing the role of the sea state, atmospheric
chemical processing, and source processes near hotspots for the availability of cloud condensation nuclei and
hence cloud formation. A set of key variables and their combinations, such as the difference between the air
and sea surface temperature, atmospheric pressure, sea surface height, geostrophic currents, upper-ocean layer
light intensity, surface wind speed and relative humidity played an important role in our analysis, highlighting
the necessity for Earth system models to represent them adequately. In conclusion, our study highlights the use
of sPCA to identify key ocean–atmosphere interactions across physical, chemical, and biological processes and
their associated spatio-temporal scales. It thereby fills an important gap between simple correlation analyses and
complex Earth system models. The sPCA processing code is available as open-access from the following link:
https://renkulab.io/gitlab/ACE-ASAID/spca-decomposition (last access: 29 March 2021). As we show here, it
can be used for an exploration of environmental data that is less prone to cognitive biases (and confirmation biases in particular) compared to traditional regression analysis that might be affected by the underlying research
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