How Green Is Satellite Monitoring? Let’s Do the Math
As more and more satellites are launched to Space, there are concerns about rocket launches’ greenhouse gas (GHG) emissions. In this article, we attempt to break down the rocket’s emission into more feasible chunks per satellite. We take a look at the concrete use case of vegetation monitoring and compare the satellites’ CO2 emissions to the more traditional approach of using helicopters. Spoiler alert: satellites win. By how much? Continue reading to find out!
The Space Industry is developing at great speed over the last few years. As key figures, 4,877 active satellites were orbiting the Earth in 2021, and this number will probably fourfold over the next ten years, as 17,000 satellites are expected to be launched to Space by 2031.
In parallel, we hear some concerns about rocket launches and greenhouse gas (GHG) emissions causing climate change and respiratory problems by trapping heat. Bringing the different pieces together, one can worry about the environmental impact of launching satellites to Space: are satellites environmentally friendly, despite the rockets’ CO2 footprint?
When it comes to Utility Vegetation Management, LiveEO’s core product, is satellite analysis a greener alternative than helicopter inspection? Reading this article, you may be (positively) surprised by the result of our documented research!
To arrive in the atmosphere, satellites are launched by rockets. If you’ve already seen images or videos of a rocket launch, you might have been impressed, but also concerned, by the heavy white smoke left behind. But what does it contain exactly? Its composition depends on the rocket and its propellant.
In case of the Falcon 9, which we will be looking at, it consists primarily of CO2, water vapor, soot, and nitrogen oxygens. In our comparison and calculation, we will focus on CO2 emissions. Both rockets and helicopters also emit other substances (and noise). Our comparison is without doubt simplified, but well suited to illustrate the magnitude of difference we are dealing with.
Let’s turn to a concrete example that we deal with at LiveEO: Vegetation Monitoring. An alternative to satellite inspection of vegetation along power lines is helicopter inspection. We look at the use case of vegetation monitoring of the German Railway network, which is the largest in Europe. How do satellites hold up against helicopters in terms of GHG emissions? Let’s look at the data.
The Eurocopter AS350-B3 is commonly used for inspection flights. This helicopter uses jet fuel. According to the Swiss Federal Office of Civil Aviation FOCA, the AS350-B3 burns roughly 160 kg of jet fuel per hour. Jet Fuel causes CO2 at a defined ratio of 3.16 kilograms of CO2 per 1 kilogram of fuel consumed. This means in one flight hour, the helicopter emits 500 kg CO2.
Let’s assume the helicopter flies at a speed of 100 km/h. They probably fly faster, but we need to account for take-off and landing and in the real world, the helicopters would also have to return to their starting point.
To cover the German railway network of 33000 km would equal to 330 flight hours (13.75 days non-stop), which would then, in turn, mean 165000 kg or 165 metric tons of CO2 emitted to fly over the entire network once with a helicopter.
Planet Labs recently sent 44 of their SuperDove satellites into orbit aboard a rideshare mission with a SpaceX Falcon 9 rocket, along with more than 50 other small satellites.
The Falcon 9 releases 425 tonnes of CO2 per launch. Broken down, this would mean you could attribute 4.25 tons of CO2 emissions to each SuperDove on that rocket.
One SuperDove satellite is capable of capturing imagery of 320,000 km² in one single day. The size of the entire country of Germany is 357,022 km². Obviously, there are more satellites involved in capturing the data as part of the constellation, just like not one single helicopter would fly over the entire network. But it would take little more than the capacity of a single satellite to capture data of the entire country.
So in the face-to-face comparison, we end up at 4,25 tons of CO2 for the satellite as part of the rocket launch versus 165 tons of CO2 for the helicopter. Important to note: The satellite’s emissions remain constant over its lifetime (one-off), while the helicopter emits with every minute its engine is running. This is an even more decisive outcome we expected before going into research.
But, it does not even end here. Satellites like the one in our example stay operative in orbit for 3-5 years and constantly collect different types of data on weather, climate, and environmental monitoring applications. For example, they can give us insights on wildfires, volcanoes, sea surface and atmospheric temperatures, precipitation, etc. During their entire lifetime, satellites collect data en passant that can make other, environmentally harmful ways of acquiring that data, obsolete.
To really understand the environmental impact of satellites, we would need to break down the emissions per measurement made by the satellite and used in the real world, and then compare it to the emissions that would have been caused by the monitoring solution they replace. How green the satellite data eventually depends on how extensively the captured data is utilized. The more insights/measurements are generated from every data point recorded, the lower will be the GHG emission share per insight. Additionally, we would need to factor in the direct benefits satellite insights have on the environment, e.g. through better-informed management of forests and other ecosystems.
Obviously, the calculation we made is heavily simplified and can only serve as an illustration for one use case where satellites can substitute environmentally harmful practices and beat them with flying colours. We did not take into account emissions by production, other GHG than CO2, emissions caused by data processing to name just a few things omitted. Interestingly, it was quite difficult to find numbers on helicopter emissions, which indicates that there is at the very least a transparency issue.
We are well aware that rockets emit CO2 and water vapor that trap outgoing thermal radiation and contribute to global warming. That is why we do not advocate for all rocket launches, like Space tourism, but for rocket launches having a meaningful purpose and bringing valuable insights to companies and people to make our planet more sustainable.
Satellites can provide us with more comprehensive knowledge of the ecosystems we live in and help us to directly mitigate risks caused by climate change. The better we learn to utilize the data satellites record, the greener it becomes.
This article was originally published by LiveEO GmbH.
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