Skip to 0 minutes and 23 secondsOne decade ago, the global climate of serving system, which is an international board-- and it supports the United Nations in their effort to tackle climate change-- had put out a list of parameters. Like the clean cut parameters, when you've got a passion you want to monitor all of them to take the head state of that passion. And this is the least of the critical parameters that we need to measure. They're called the essential climate values. And guess what-- from space, from satellites, we can monitor many of those parameters and get a very good estimate of those.
Skip to 1 minute and 7 secondsYou will have seen examples for ocean coral, for sea surface temperature, and in particular, the rise in sea level that we see from space. This is really a crucial parameter, an indicator, of climate change on our planet. And the European Space Agency has launched already, five years ago, the Climate Change Initiative to monitor essential climate valuable from space. This is the result of the climate change initiative for sea level. But then there are similar results looking at sea surface temperature or ocean corridor and other parameters.
Skip to 1 minute and 45 secondsFor sea level, what people have done working into this huge project lead by CLS of France-- is looking at the data, making the data more accurate, improving everything that was possible in the various corrections and in the various algorithms that you used to extract the information from their old data-- so that you would get a better estimate, you would get a more accurate estimate of the rising sea level, and have more confidence in what you see. Of course, it is quite a lot of work that involves integrating these kinds of measurements with in situ measurements which remain important-- like measurements from tide gauges and measurements from floats, like the Argo floats.
Skip to 2 minutes and 31 secondsSo it's not just space, but space will give you the global picture. And satellites will give you the global picture. And in combination with in situ data, you get the accuracy that is needed for these kind of applications. This is also important, because we are really now starting to benefit from many years of investments by European tax payers into satellites. That we can now use those data to see what is going on in the long term. We've got 20 years of data from satellites alone, and we can confirm that we've seen a steady increase of sea level at three millimetres per year.
Skip to 3 minutes and 16 secondsSo this global beta data product was produced from a range of European Space Agency sensors over different time periods and different spatial resolution, which is one of the challenges of producing products like this-- of merging these different data sets. And so this particular data set included data from the spot VGT sensor, from the MERIS sensor, and from the ATSR family of sensors. And the approach that was taken was developed in such a way that when new observations come on stream, from the Sentinel programme, for example, they could be incorporated into this processing chain. And we can extend this global production beyond the present day and into the future, as we collect and collate new observations at different times by scales.
Skip to 4 minutes and 4 secondsA product like this was developed in response to a number of different requirements, but one of the chief requirements for this was the ESA CCI, or climate change initiative. And essentially, that identifies a number of key observations that are required for understanding climate change and asking the scientific community to define what those observations might be, the precision of measurement of those observations that is required in order to improve our understanding, and in essence, to define the kind of parameters that we should be measuring and that we should be targeting, if not now, in the future when we develop new sensor programmes and systems.
Skip to 4 minutes and 49 secondsAnd so that kind of approach means that we're looking very much at developing long time continuity of sensors and observations. And so a very good example of this takes various observations that have been made over the last 10 or 15 years by a variety of different sensors, such as a MERIS and other instruments on board the ENVISAT platform, and says, OK, can we carry on the legacy of those instruments in such a way as the observations can be seamlessly integrated over time and space and then, even better, augmented with other observations that have improved capabilities in terms of the wavelengths resolution-- in terms of the space and time resolution.
Skip to 5 minutes and 35 secondsThe Climate Change Initiative programme is very useful in bringing together all the international expertise in different types of data from across Europe. And the purpose is really to be able to go back in time, look again at data that were collected over the several decades, and bring them up to a standard that can be used for climate studies. For climate, you need to be able to compare, for example, the sea surface temperature from one year with another year maybe 20 years before. This is not what these sensors were originally designed for. And so in the CCI, we use a range of techniques to bring that degree of compatibility across time which is required for climate studies.
Skip to 6 minutes and 18 secondsPreviously, we've had ocean colour data from three or four different satellites. You can't directly compare the information that you're getting from each of those satellites. And that's because their slightly different instruments. They have slightly different characteristics. And they use algorithms, which is slightly different, to extract chlorophyll. So one of the really important things that the CCI has been doing is to try and make all of those data sets consistent. So to make a data set which we can reliably know that if we see a change in the data, it's genuinely due to a long term trend and not just an artefact because of change in instrumentation or satellites.
Skip to 6 minutes and 53 secondsOne of the important developments, recently, with the ESA Climate Change Initiative is that they're not just taking the satellite ocean colour records, but they're also integrating those observations with other in situ data, such as from ships for example, or increasingly from autonomous technologies such as moorings, floats et cetera, which give us real estimates of chlorophyll concentration in the ocean, which we can then use to validate our satellite data. We currently have about 16 years off satellite ocean colour data. That's been absolutely revolutionary in our understanding of how phytoplankton populations change. That's mostly in response to natural variability.
Skip to 7 minutes and 30 secondsSo the same way that plants on the land go through a seasonal cycle-- they bloom in spring and die off in autumn-- so do phytoplankton, the plants in the ocean. So the satellite data has been able to tell us about that aspect. But it's also been able to tell us about longer term change as well, in the context of climate change. Unfortunately, 16 years of data sounds like a lot, but when you're trying to look at a long term change, as climate change is, it's really not enough. And some recent research that we've done has demonstrated that actually you need more like 30 years of continuous ocean colour data to see a long term trend.
Skip to 8 minutes and 5 secondsAnd that's because the natural variability in phytoplankton is really large. Unfortunately, if the satellite record, for some reason is broken, perhaps a failure of one or more satellites, that actually increases the amount of data that we need to see that climate change trend. It increases from around 30 years to around 60 years of data. So I'll be in a retirement home by then, so I don't want that to happen. So it's really key that we can keep these long, continuous, consistent records going.
Topic 5a - ESA Climate Change Initiative
Welcome to Week 5. This week will look at how Earth observation data are managed, the current methods used and some of the future challenges for handling and accessing large amounts of EO data.
ESA’s Climate Change Initiative (CCI) is instrumental in supporting the long term monitoring of a series of so-called ‘Essential Climate Variables’ (ECVs). The Climate Change Initiative focuses on key ECVs that can be assessed from space, potentially almost continuously and over long time scales. This includes a range of variables such as ocean colour, greenhouse gases, atmospheric aerosols, sea level, sea ice, land cover and burned area. Observations from space allow consistent and comparable measurements of these ECVs to be taken across the globe, providing valuable long term information about the effects, and in some cases also the contributing drivers, of climate-related changes in these environmental variables. EO data also provides information on the degree of natural variability that can be expected in these aspects of the Earth system.
In this video, we explore how ESA’s CCI is advancing our understanding of climate-related changes associated with a number of ECVs, in part by enabling observations from different satellite missions and instruments to be confidently blended into a single, consistent longer-term record, with well understood uncertainties, which can be used to study both trends and natural variability.
- Dr Mathias Disney
Other Featured Experts:
- Dr Paolo Cipollini
- Professor Chris Merchant
- Dr Stephanie Henson
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Explore the Imagery, Data and Satellites:
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