Summary:
Rising greenhouse gas emissions could significantly reduce the number of satellites that can safely operate in low Earth orbit, according to a study published in Nature Sustainability.
Researchers from MIT report that carbon dioxide and other greenhouse gases are causing the upper atmosphere to shrink, decreasing atmospheric drag โ the force that naturally removes old satellites and space debris by pulling them into lower altitudes where they burn up. As a result, more debris will persist in orbit, raising collision risks and limiting space for future satellites. Simulations conducted by the team suggest that by 2100, the โcarrying capacityโ of key orbital regions could decline by 50-66%, making space increasingly congested.
With satellite launches increasing rapidly, including large fleets like Starlink, the study highlights the need to manage emissions and orbital traffic to prevent long-term instability in Earth‘s orbit.
Climate change will reduce the number of satellites that can safely orbit in space
MIT aerospace engineers have found that greenhouse gas emissions are changing the environment of near-Earth space in ways that, over time, will reduce the number of satellites that can sustainably operate there.
In this study, the researchers report that carbon dioxide and other greenhouse gases can cause the upper atmosphere to shrink. An atmospheric layer of special interest is the thermosphere, where the International Space Station and most satellites orbit today. When the thermosphere contracts, the decreasing density reduces atmospheric drag โ a force that pulls old satellites and other debris down to altitudes where they will encounter air molecules and burn up.
Less drag therefore means extended lifetimes for space junk, which will litter sought-after regions for decades and increase the potential for collisions in orbit.
The team carried out simulations of how carbon emissions affect the upper atmosphere and orbital dynamics, in order to estimate the โsatellite carrying capacityโ of low Earth orbit. These simulations predict that by the year 2100, the carrying capacity of the most popular regions could be reduced by 50-66 percent due to the effects of greenhouse gases.
โOur behavior with greenhouse gases here on Earth over the past 100 years is having an effect on how we operate satellites over the next 100 years,โ says study author Richard Linares, associate professor in MITโs Department of Aeronautics and Astronautics (AeroAstro).
โThe upper atmosphere is in a fragile state as climate change disrupts the status quo,โ adds lead author William Parker, a graduate student in AeroAstro. โAt the same time, thereโs been a massive increase in the number of satellites launched, especially for delivering broadband internet from space. If we donโt manage this activity carefully and work to reduce our emissions, space could become too crowded, leading to more collisions and debris.โ
The study includes co-author Matthew Brown of the University of Birmingham.
Sky fall
The thermosphere naturally contracts and expands every 11 years in response to the sunโs regular activity cycle. When the sunโs activity is low, the Earth receives less radiation, and its outermost atmosphere temporarily cools and contracts before expanding again during solar maximum.
In the 1990s, scientists wondered what response the thermosphere might have to greenhouse gases. Their preliminary modeling showed that, while the gases trap heat in the lower atmosphere, where we experience global warming and weather, the same gases radiate heat at much higher altitudes, effectively cooling the thermosphere. With this cooling, the researchers predicted that the thermosphere should shrink, reducing atmospheric density at high altitudes.
In the last decade, scientists have been able to measure changes in drag on satellites, which has provided some evidence that the thermosphere is contracting in response to something more than the sunโs natural, 11-year cycle.
โThe sky is quite literally falling โ just at a rate thatโs on the scale of decades,โ Parker says. โAnd we can see this by how the drag on our satellites is changing.โ
The MIT team wondered how that response will affect the number of satellites that can safely operate in Earthโs orbit. Today, there are over 10,000 satellites drifting through low Earth orbit, which describes the region of space up to 1,200 miles (2,000 kilometers), from Earthโs surface. These satellites deliver essential services, including internet, communications, navigation, weather forecasting, and banking.
The satellite population has ballooned in recent years, requiring operators to perform regular collision-avoidance maneuvers to keep safe. Any collisions that do occur can generate debris that remains in orbit for decades or centuries, increasing the chance for follow-on collisions with satellites, both old and new.
โMore satellites have been launched in the last five years than in the preceding 60 years combined,โ Parker says. โOne of key things weโre trying to understand is whether the path weโre on today is sustainable.โ
Crowded shells
In their new study, the researchers simulated different greenhouse gas emissions scenarios over the next century to investigate impacts on atmospheric density and drag. For each โshell,โ or altitude range of interest, they then modeled the orbital dynamics and the risk of satellite collisions based on the number of objects within the shell. They used this approach to identify each shellโs โcarrying capacityโ โ a term that is typically used in studies of ecology to describe the number of individuals that an ecosystem can support.
โWeโre taking that carrying capacity idea and translating it to this space sustainability problem, to understand how many satellites low Earth orbit can sustain,โ Parker explains.
The team compared several scenarios: one in which greenhouse gas concentrations remain at their level from the year 2000 and others where emissions change according to the Intergovernmental Panel on Climate Change (IPCC) Shared Socioeconomic Pathways (SSPs). They found that scenarios with continuing increases in emissions would lead to a significantly reduced carrying capacity throughout low Earth orbit.
In particular, the team estimates that by the end of this century, the number of satellites safely accommodated within the altitudes of 200 and 1,000 kilometers could be reduced by 50 to 66 percent compared with a scenario in which emissions remain at year-2000 levels. If satellite capacity is exceeded, even in a local region, the researchers predict that the region will experience a โrunaway instability,โ or a cascade of collisions that would create so much debris that satellites could no longer safely operate there.
Their predictions forecast out to the year 2100, but the team says that certain shells in the atmosphere today are already crowding up with satellites, particularly from recent โmegaconstellationsโ such as SpaceXโs Starlink, which comprises fleets of thousands of small internet satellites.
โThe megaconstellation is a new trend, and weโre showing that because of climate change, weโre going to have a reduced capacity in orbit,โ Linares says. โAnd in local regions, weโre close to approaching this capacity value today.โ
โWe rely on the atmosphere to clean up our debris. If the atmosphere is changing, then the debris environment will change too,โ Parker adds. โWe show the long-term outlook on orbital debris is critically dependent on curbing our greenhouse gas emissions.โ
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This research is supported, in part, by the U.S. National Science Foundation, the U.S. Air Force, and the U.K. Natural Environment Research Council.
Journal Reference:
Parker, W.E., Brown, M.K. & Linares, R., ‘Greenhouse gases reduce the satellite carrying capacity of low Earth orbit’, Nature Sustainability (2025). DOI: 10.1038/s41893-025-01512-0
Article Source:
Press Release/Material by Jennifer Chu | Massachusetts Institute of Technology
Featured image credit: NASA | Unsplash
