Difference between revisions of "Green Ocean modelling"
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− | == | + | {{Review |name=Peter Herman|AuthorID=79}} |
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+ | '''A tool to understand the interactions between marine ecosystems and climate''' | ||
==Background== | ==Background== | ||
The Earth’s climate is changing. Indeed warmer temperatures, changes in precipitation, ice cover, river fluxes and atmospheric dust deposition have all been observed in recent decades. In addition, the ocean surface has become more acidic due to the absorption of increased atmospheric carbon dioxide (CO<sub>2</sub>). How do these changes impact marine ecosystems? To answer this we need better models capable of capturing the dynamics of marine ecosystems, and adequate and continued ocean observation programmes. | The Earth’s climate is changing. Indeed warmer temperatures, changes in precipitation, ice cover, river fluxes and atmospheric dust deposition have all been observed in recent decades. In addition, the ocean surface has become more acidic due to the absorption of increased atmospheric carbon dioxide (CO<sub>2</sub>). How do these changes impact marine ecosystems? To answer this we need better models capable of capturing the dynamics of marine ecosystems, and adequate and continued ocean observation programmes. | ||
+ | __FORCETOC__ | ||
− | + | <br> | |
+ | ====Why is ecosystem dynamics so important for interpreting climate change impacts?==== | ||
Firstly, because of the nature of food webs in the ocean. Phytoplankton, the smallest marine organisms, transform energy from the sun into organic tissue. Phytoplankton are eaten by zooplankton, which are eaten by small fish, and these by bigger fish and so on. Changes in the abundance, type and distribution of phyto- and zoo-plankton result in complex impacts on the distribution and production of fish populations. | Firstly, because of the nature of food webs in the ocean. Phytoplankton, the smallest marine organisms, transform energy from the sun into organic tissue. Phytoplankton are eaten by zooplankton, which are eaten by small fish, and these by bigger fish and so on. Changes in the abundance, type and distribution of phyto- and zoo-plankton result in complex impacts on the distribution and production of fish populations. | ||
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==What is Green Ocean Modelling?== | ==What is Green Ocean Modelling?== | ||
Dynamic Green Ocean Models are mathematical representations of the ocean which include ocean currents, chemical processes and a representation of marine ecosystems that is based on the concept of Plankton Functional Types (PFTs). Plankton both responds to, and influences climate. In order to quantify and understand the interactions between marine ecosystems and climate, [[phytoplankton]] and [[zooplankton]] communities are simplified in the model into PFTs according to their size and functional role (Figure 1). | Dynamic Green Ocean Models are mathematical representations of the ocean which include ocean currents, chemical processes and a representation of marine ecosystems that is based on the concept of Plankton Functional Types (PFTs). Plankton both responds to, and influences climate. In order to quantify and understand the interactions between marine ecosystems and climate, [[phytoplankton]] and [[zooplankton]] communities are simplified in the model into PFTs according to their size and functional role (Figure 1). | ||
− | + | We use observations to describe the dynamics of the various PFTs. Observations include laboratory work or physiological studies under controlled laboratory conditions, where the concentrations of nutrients or the water acidity are manipulated and the response of the ecosystem or its parts is monitored. These experiments allow us to quantify the growth and mortality of the PFTs. | |
− | + | Some PFTs share common characteristics such as growth rates, survival strategies, and the response to temperature and light. Zooplankton PFTs typically eat prey 2 to 10 times smaller than themselves, and produce fecal pellets that sink and transport carbon and nutrients to the deep ocean. Finally, observations that give a large-scale picture of the abundance and distribution of each PFT are used to evaluate whether the representation of the ecosystem in the models is accurate and if the model reproduces the basic features such as the seasonal cycle of the PFTs. When the observations and models have been put together and evaluated, the resulting Dynamic Green Ocean Model can be used to estimate how ecosystems respond to different climatic conditions and if this response could affect food production or cause dangerous feedbacks on the climate. | |
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− | + | {| border="1" width="500" align="center" | |
− | + | |style="border: 0px;" |<div style="text-align: left;font-size:100%;color: #6A5ACD;padding:1em 1em 1em 1em">'''''Bacteria'''''</div> | |
− | + | |style="border: 0px;" |[[Image:0307.picohetero.PNG|caption|center|80px|]] | |
− | + | | style="border: 0px;" |<div style="font-size:90%;color: #6A5ACD;padding:1em 1em 1em 1em">'''pico-heterotrophs; remineralise dissolved and particulate organic matter'''</div> | |
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− | {| border="1" | ||
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− | |<div style="text-align: left;font-size:100%;color: #6A5ACD;padding:1em 1em 1em 1em">'''''Bacteria'''''</div> | ||
− | |[[Image:0307.picohetero.PNG|caption|center|80px|]] | ||
− | | <div style="font-size:90%;color: #6A5ACD;padding:1em 1em 1em 1em">'''pico-heterotrophs; remineralise dissolved and particulate organic matter'''</div> | ||
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− | | | + | |style="border: 0px;" | |
− | | [[Image:0307.picoauto.PNG|caption|center|80px|]] | + | |style="border: 0px;" | [[Image:0307.picoauto.PNG|caption|center|80px|]] |
− | |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''pico-autotrophs; contribute to primary production but not to export of carbon'''</div> | + | |style="border: 0px;" |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''pico-autotrophs; contribute to primary production but not to export of carbon'''</div> |
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− | | | + | |style="border: 0px;" | |
− | |[[Image:0307.n2fixers.PNG|caption|center|80px|]] | + | |style="border: 0px;" |[[Image:0307.n2fixers.PNG|caption|center|80px|]] |
− | |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''N<sub>2</sub>-fixers; control total amount of reactive N'''</div> | + | |style="border: 0px;" |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''N<sub>2</sub>-fixers; control total amount of reactive N'''</div> |
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− | | | + | |style="border: 0px;" | |
− | |[[Image:0307.coco.PNG|caption|center|80px|]] | + | |style="border: 0px;" |[[Image:0307.coco.PNG|caption|center|80px|]] |
− | |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''calcifiers; produce more than half the marine carbonate flux, sensitive to pH'''</div> | + | |style="border: 0px;" |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''calcifiers; produce more than half the marine carbonate flux, sensitive to pH'''</div> |
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− | |<div style="text-align: left;font-size:100%;color: #2E8B57;padding:1em 1em 1em 1em">'''''Phytoplankton'''''</div> | + | |style="border: 0px;" |<div style="text-align: left;font-size:100%;color: #2E8B57;padding:1em 1em 1em 1em">'''''Phytoplankton'''''</div> |
− | |[[Image:0307.DMS.PNG|caption|center|80px|]] | + | |style="border: 0px;" |[[Image:0307.DMS.PNG|caption|center|80px|]] |
− | |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''DMS-producers; influence atmospheric sulphur cycle'''</div> | + | |style="border: 0px;" |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''DMS-producers; influence atmospheric sulphur cycle'''</div> |
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− | | | + | |style="border: 0px;" | |
− | |[[Image:0307.mixed.PNG|caption|center|80px|]] | + | |style="border: 0px;" |[[Image:0307.mixed.PNG|caption|center|80px|]] |
− | |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''mixed; the background biomass of phytoplankton'''</div> | + | |style="border: 0px;" |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''mixed; the background biomass of phytoplankton'''</div> |
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− | | | + | |style="border: 0px;" | |
− | |[[Image:0307.silicifiers.PNG|caption|center|80px|]] | + | |style="border: 0px;" |[[Image:0307.silicifiers.PNG|caption|center|80px|]] |
− | |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''silicifiers; contribute to export of carbon to deep ocean'''</div> | + | |style="border: 0px;" |<div style="font-size:90%;color: #2E8B57;padding:1em 1em 1em 1em">'''silicifiers; contribute to export of carbon to deep ocean'''</div> |
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− | | | + | |style="border: 0px;" | |
− | |[[Image:0307.proto.PNG|caption|center|80px|]] | + | |style="border: 0px;" |[[Image:0307.proto.PNG|caption|center|80px|]] |
− | |<div style="font-size:90%;color: #FF0000;padding:1em 1em 1em 1em">'''proto; graze on small phytoplankton, control blooms'''</div> | + | |style="border: 0px;" |<div style="font-size:90%;color: #FF0000;padding:1em 1em 1em 1em">'''proto; graze on small phytoplankton, control blooms'''</div> |
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− | |<div style="text-align: left;font-size:100%;color: #FF0000;padding:1em 1em 1em 1em">'''''Zooplankton'''''</div> | + | |style="border: 0px;" |<div style="text-align: left;font-size:100%;color: #FF0000;padding:1em 1em 1em 1em">'''''Zooplankton'''''</div> |
− | |[[Image:0307.meso.PNG|caption|center|80px|]] | + | |style="border: 0px;" |[[Image:0307.meso.PNG|caption|center|80px|]] |
− | |<div style="font-size:90%;color: #FF0000;padding:1em 1em 1em 1em">'''meso; graze on all sizes of plankton, produce fast-sinking faecal pellets which export carbon'''</div> | + | |style="border: 0px;" |<div style="font-size:90%;color: #FF0000;padding:1em 1em 1em 1em">'''meso; graze on all sizes of plankton, produce fast-sinking faecal pellets which export carbon'''</div> |
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− | | | + | |style="border: 0px;" | |
− | |[[Image:0307.macro.PNG|caption|center|80px|]] | + | |style="border: 0px;" |[[Image:0307.macro.PNG|caption|center|80px|]] |
− | |<div style="font-size:90%;color: #FF0000;padding:1em 1em 1em 1em">'''macro; graze on all sizes of phyto-plankton and produce fast-sinking faecal pellets'''</div> | + | |style="border: 0px;" |<div style="font-size:90%;color: #FF0000;padding:1em 1em 1em 1em">'''macro; graze on all sizes of phyto-plankton and produce fast-sinking faecal pellets'''</div> |
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|colspan="3" align="center" |'''Figure 1.''' Ten PFTs were identified that need to be simulated explicitly in order to capture important biogeochemical processes in the ocean. | |colspan="3" align="center" |'''Figure 1.''' Ten PFTs were identified that need to be simulated explicitly in order to capture important biogeochemical processes in the ocean. | ||
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+ | ==What do Green Ocean Models tell us?== | ||
+ | [[Image:0307.greenoceanFIG2.PNG |thumb|420px|align:center|'''Figure 2''' Change in the oceanic sink for CO2 (mol/m<sup>2</sup>/y) caused by shifts in ecosystem composition projected for year 2060 and estimated with a Dynamic Green Ocean Model which includes 5 Plankton Functional Types. A model with 10 Plankton Functional Types is currently under development. Negative values denote net flux of CO2 from atmosphere to seawater, and positive values indicate reduced CO2 flux into seawater.|frame]] | ||
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Dynamic Green Ocean Models are powerful tools capable of resolving and predicting the functioning of marine ecosystems based on actual or theoretical climate change scenarios. Preliminary model results are already available and indicate large shifts in ecosystem composition triggered by the changing climate conditions. These model results also show local modifications in the fluxes of CO<sub>2</sub> between the atmosphere and seawater as a result of changes in ecosystem composition (Figure 2.). Dynamic Green Ocean Models are specifically designed to estimate the impact that changes in ecosystem composition may have on the climate. | Dynamic Green Ocean Models are powerful tools capable of resolving and predicting the functioning of marine ecosystems based on actual or theoretical climate change scenarios. Preliminary model results are already available and indicate large shifts in ecosystem composition triggered by the changing climate conditions. These model results also show local modifications in the fluxes of CO<sub>2</sub> between the atmosphere and seawater as a result of changes in ecosystem composition (Figure 2.). Dynamic Green Ocean Models are specifically designed to estimate the impact that changes in ecosystem composition may have on the climate. | ||
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Results of Dynamic Green Ocean Models are still difficult to interpret because of the lack of real observations capable of evaluating and validating the models. Data syntheses have been partly done for some PFTs, but field observations are currently too limited, and have considerable geographical and temporal scatter to really constrain the models. '''There is a pressing need for more field observations as well as improved theoretical understanding of the linkages between and within PFTs to increase model reliability and trust'''. Satellite data are also extremely valuable although satellite imagery is indirect and often difficult to interpret. There are at least six Dynamic Green Ocean Models world wide, including in the UK, France, Germany, Italy, the US and Japan. Some models are being coupled to Climate models to assess the complete interactions between changes in ecosystems and changes in climate. It is hoped that their full development and evaluation will provide reliable estimates of the consequences of changes in marine ecosystems dynamics on the Earth’s climate and on marine food resources, and thus help guide policy makers. | Results of Dynamic Green Ocean Models are still difficult to interpret because of the lack of real observations capable of evaluating and validating the models. Data syntheses have been partly done for some PFTs, but field observations are currently too limited, and have considerable geographical and temporal scatter to really constrain the models. '''There is a pressing need for more field observations as well as improved theoretical understanding of the linkages between and within PFTs to increase model reliability and trust'''. Satellite data are also extremely valuable although satellite imagery is indirect and often difficult to interpret. There are at least six Dynamic Green Ocean Models world wide, including in the UK, France, Germany, Italy, the US and Japan. Some models are being coupled to Climate models to assess the complete interactions between changes in ecosystems and changes in climate. It is hoped that their full development and evaluation will provide reliable estimates of the consequences of changes in marine ecosystems dynamics on the Earth’s climate and on marine food resources, and thus help guide policy makers. | ||
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<div style="border:1px solid #000000;float: right; background-color:#FFD700; padding:0.5em 0.5em 2em 0.5em; font-size:100%"> | <div style="border:1px solid #000000;float: right; background-color:#FFD700; padding:0.5em 0.5em 2em 0.5em; font-size:100%"> | ||
− | + | ==Action Points== | |
− | Large-scale monitoring and data syntheses for Plankton Functional Types are required to evaluate the results of the Green Ocean models. This includes the measurement of PFTs by microscopic counts, flow cytometry, pigments data analysis or imaging techniques. | + | *Large-scale monitoring and data syntheses for Plankton Functional Types are required to evaluate the results of the Green Ocean models. This includes the measurement of PFTs by microscopic counts, [[Flow cytometer | flow cytometry]], pigments data analysis or imaging techniques. |
+ | *The development of Earth System Models that include advanced representations of marine ecosystems to understand and quantify the two-way interactions between ecosystems and climate. | ||
</div> | </div> | ||
+ | |||
+ | {| | ||
+ | |} | ||
+ | |||
+ | |||
+ | <div style="background:#006699;float: right; | ||
+ | padding:0.5em 0.5em 0.5em 0.5em; font-size:100%; color:#FFFFFF"> | ||
+ | '''Fact Sheet by: EUR-OCEANS Knowledge Transfer Unit, hosted by the GLOBEC IPO at Plymouth Marine Laboratory. For further information contact, Jessica Heard: jessh@pml.ac.uk or visit the Website: www.eur-oceans.org/KTU''' | ||
+ | </div> | ||
+ | {| | ||
+ | |} | ||
{{Credits | {{Credits | ||
|photos= | |photos= | ||
− | [[Image:SouzaDias.0307.BritishArcticS. | + | [[Image:SouzaDias.0307.BritishArcticS.jpeg|150px|]] |
|abstract= | |abstract= | ||
− | <div style="font-size: | + | <div style="font-size:95%;color: #000000;padding:0em 0em 0em 0em">This Wiki page was adapted from [http://www.eur-oceans.eu/?q=node/18116 EUR-OCEANS Fact Sheet no. 6] composed by Corinne Le Quéré, Co-ordinator of the Dynamic Green Ocean Project. For further information please see http://lgmacweb.env.uea.ac.uk/green_ocean/ or contact Corinne (c.lequere@uea.ac.uk). The development of Dynamic Green Ocean Models requires the co-ordination of efforts among modellers and observationalists. We acknowledge input from the participants of the Dynamic Green Ocean Workshops held in Villefranche-sur-mer annually since 2001 as well as continued support from the Max-Planck-Institute for Biogeochemistry (Germany), the UK QUEST office and the European Union through various projects. </div>}} |
+ | |||
+ | [[Category:Euroceans fact sheets]] | ||
+ | [[Category:Coastal and marine ecosystems]] | ||
+ | [[Category:Climate change, impacts and adaptation]] |
Latest revision as of 15:18, 12 September 2023
A tool to understand the interactions between marine ecosystems and climate
Contents
Background
The Earth’s climate is changing. Indeed warmer temperatures, changes in precipitation, ice cover, river fluxes and atmospheric dust deposition have all been observed in recent decades. In addition, the ocean surface has become more acidic due to the absorption of increased atmospheric carbon dioxide (CO2). How do these changes impact marine ecosystems? To answer this we need better models capable of capturing the dynamics of marine ecosystems, and adequate and continued ocean observation programmes.
Why is ecosystem dynamics so important for interpreting climate change impacts?
Firstly, because of the nature of food webs in the ocean. Phytoplankton, the smallest marine organisms, transform energy from the sun into organic tissue. Phytoplankton are eaten by zooplankton, which are eaten by small fish, and these by bigger fish and so on. Changes in the abundance, type and distribution of phyto- and zoo-plankton result in complex impacts on the distribution and production of fish populations.
Secondly, because marine ecosystems have an influence on the composition of gases in the atmosphere. Indeed, the production and sinking of organic particles in the oceans helps regulate the concentration of the main greenhouse gas, CO2. Without the action of marine ecosystems atmospheric CO2 would be 1.5 times higher than it is today. Any changes in marine ecosystems could have an impact on atmospheric CO2. Marine ecosystems also emit other greenhouse gases and DMS (dimethyl sulfide), which has a cooling effect on climate.
What is Green Ocean Modelling?
Dynamic Green Ocean Models are mathematical representations of the ocean which include ocean currents, chemical processes and a representation of marine ecosystems that is based on the concept of Plankton Functional Types (PFTs). Plankton both responds to, and influences climate. In order to quantify and understand the interactions between marine ecosystems and climate, phytoplankton and zooplankton communities are simplified in the model into PFTs according to their size and functional role (Figure 1). We use observations to describe the dynamics of the various PFTs. Observations include laboratory work or physiological studies under controlled laboratory conditions, where the concentrations of nutrients or the water acidity are manipulated and the response of the ecosystem or its parts is monitored. These experiments allow us to quantify the growth and mortality of the PFTs. Some PFTs share common characteristics such as growth rates, survival strategies, and the response to temperature and light. Zooplankton PFTs typically eat prey 2 to 10 times smaller than themselves, and produce fecal pellets that sink and transport carbon and nutrients to the deep ocean. Finally, observations that give a large-scale picture of the abundance and distribution of each PFT are used to evaluate whether the representation of the ecosystem in the models is accurate and if the model reproduces the basic features such as the seasonal cycle of the PFTs. When the observations and models have been put together and evaluated, the resulting Dynamic Green Ocean Model can be used to estimate how ecosystems respond to different climatic conditions and if this response could affect food production or cause dangerous feedbacks on the climate.
Bacteria
|
pico-heterotrophs; remineralise dissolved and particulate organic matter
| |
pico-autotrophs; contribute to primary production but not to export of carbon
| ||
N2-fixers; control total amount of reactive N
| ||
calcifiers; produce more than half the marine carbonate flux, sensitive to pH
| ||
Phytoplankton
|
DMS-producers; influence atmospheric sulphur cycle
| |
mixed; the background biomass of phytoplankton
| ||
silicifiers; contribute to export of carbon to deep ocean
| ||
proto; graze on small phytoplankton, control blooms
| ||
Zooplankton
|
meso; graze on all sizes of plankton, produce fast-sinking faecal pellets which export carbon
| |
macro; graze on all sizes of phyto-plankton and produce fast-sinking faecal pellets
| ||
Figure 1. Ten PFTs were identified that need to be simulated explicitly in order to capture important biogeochemical processes in the ocean. |
What do Green Ocean Models tell us?
Dynamic Green Ocean Models are powerful tools capable of resolving and predicting the functioning of marine ecosystems based on actual or theoretical climate change scenarios. Preliminary model results are already available and indicate large shifts in ecosystem composition triggered by the changing climate conditions. These model results also show local modifications in the fluxes of CO2 between the atmosphere and seawater as a result of changes in ecosystem composition (Figure 2.). Dynamic Green Ocean Models are specifically designed to estimate the impact that changes in ecosystem composition may have on the climate.
Results of Dynamic Green Ocean Models are still difficult to interpret because of the lack of real observations capable of evaluating and validating the models. Data syntheses have been partly done for some PFTs, but field observations are currently too limited, and have considerable geographical and temporal scatter to really constrain the models. There is a pressing need for more field observations as well as improved theoretical understanding of the linkages between and within PFTs to increase model reliability and trust. Satellite data are also extremely valuable although satellite imagery is indirect and often difficult to interpret. There are at least six Dynamic Green Ocean Models world wide, including in the UK, France, Germany, Italy, the US and Japan. Some models are being coupled to Climate models to assess the complete interactions between changes in ecosystems and changes in climate. It is hoped that their full development and evaluation will provide reliable estimates of the consequences of changes in marine ecosystems dynamics on the Earth’s climate and on marine food resources, and thus help guide policy makers.
Action Points
- Large-scale monitoring and data syntheses for Plankton Functional Types are required to evaluate the results of the Green Ocean models. This includes the measurement of PFTs by microscopic counts, flow cytometry, pigments data analysis or imaging techniques.
- The development of Earth System Models that include advanced representations of marine ecosystems to understand and quantify the two-way interactions between ecosystems and climate.
Fact Sheet by: EUR-OCEANS Knowledge Transfer Unit, hosted by the GLOBEC IPO at Plymouth Marine Laboratory. For further information contact, Jessica Heard: jessh@pml.ac.uk or visit the Website: www.eur-oceans.org/KTU
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