An average of about one tracked object per day has been dropping out of orbit for the past 50 years, In addition to natural atmospheric effects, corporations, academics and government agencies have proposed plans and technology to deal with space debris, but , most of these are theoretical, and there is no business plan for debris reduction. The different methods for removal of space debris have been evaluated by the
Space Generation Advisory Council, including French astrophysicist
Fatoumata Kébé. In May 2024, a NASA report from the Office of Technology, Policy, and Strategy introduced new methods for addressing orbital debris. The report, titled
Cost and Benefit Analysis of Mitigating, Tracking, and Remediating Orbital Debris, provided a comprehensive analysis comparing the cost-effectiveness of over ten different actions, including shielding spacecraft, tracking smaller debris, and removing large debris. By evaluating these measures in economic terms, the study aims to inform cost-effective strategies for debris management, highlighting that methods like rapid deorbiting of defunct spacecraft can significantly reduce risks in space.
National and international regulation There is no international treaty minimizing space debris. However, the
United Nations Committee on the Peaceful Uses of Outer Space (COPUOS) published voluntary guidelines in 2007, using a variety of earlier national regulatory attempts at developing standards for debris mitigation. As of 2008, the committee was discussing international "rules of the road" to prevent collisions between satellites. By 2013, a number of national legal regimes existed, The US issued a set of standard practices for civilian (NASA) and military (
DoD and USAF) orbital-debris mitigation in 2001. There is no consensus however on what any new timeframe might be. which was a predecessor standard to the ISO international standard work that would begin the following year. In 2008, ESA further developed "its own "Requirements on Space Debris Mitigation for Agency Projects" which "came into force on 1 April 2008." The "direct retrieval" option (option no. 3 in the US "standard practices" above) has rarely been done by any spacefaring nation (exception, USAF
X-37) or commercial actor since the earliest days of spaceflight due to the cost and complexity of achieving direct retrieval, but the ESA has scheduled a 2026 demonstration mission (
ClearSpace-1) to do this with a single small satellite (
PROBA-1) at a projected cost of €120 million not including the launch costs. In 2007, the
ISO began preparing an
international standard for space-debris mitigation. By 2010, ISO had published "a comprehensive set of space system engineering standards aimed at mitigating space debris. [with primary requirements] defined in the top-level standard,
ISO 24113." By 2017, the standards were nearly complete. However, these standards are not binding on any party by ISO or any international jurisdiction. They are simply available for use in voluntary ways. They "can be adopted voluntarily by a spacecraft manufacturer or operator, or brought into effect through a commercial contract between a customer and supplier, or used as the basis for establishing a set of national regulations on space debris mitigation." representing space debris in low earth orbit at the current rate of growth compared to mitigation measures being taken The voluntary ISO standard also adopted the "25-year rule" for the "LEO protected region" below altitude that has been previously (and still is, ) used by the US, ESA, and UN mitigation standards, and identifies it as "an upper limit for the amount of time that a space system shall remain in orbit after its mission is completed. Ideally, the time to deorbit should be as short as possible (i.e., much shorter than 25 years)".
Growth mitigation As of the 2010s, several technical approaches to the mitigation of the growth of space debris are typically undertaken, yet no comprehensive legal regime or cost assignment structure is in place to reduce space debris in the way that terrestrial pollution has reduced since the mid-20th century. International mitigation guidance has been published to reduce the creation of new debris, including recommendations to minimize debris released during normal operations, prevent on-orbit breakups, and perform post-mission disposal and collision-avoidance planning. NASA has also published detailed engineering guidance for limiting orbital debris as part of its technical standards documentation. To avoid excessive creation of artificial space debris, manybut not allsatellites launched to above-low-Earth-orbit are launched initially into
elliptical orbits with
perigees inside Earth's atmosphere so the orbit will quickly decay and the satellites then will be destroyed upon
reentry into the atmosphere. Other methods are used for spacecraft in higher orbits. These include
passivation of the spacecraft at the end of its useful life; as well as the use of upper stages that can reignite to decelerate the stage to intentionally deorbit it, often on the first or second orbit following payload release; satellites that can, if they remain healthy for years, deorbit themselves from the lower orbits around Earth. Other satellites (such as many CubeSats) in low orbits below approximately orbital altitude depend on the energy-absorbing effects of the upper atmosphere to reliably deorbit a spacecraft within weeks or months. Increasingly,
spent upper stages in higher orbitsorbits for which low-delta-v deorbit is not possible, or not planned forand architectures that support satellite passivation, are passivated at end of life. This removes any internal energy contained in the vehicle at the end of its mission or useful life. While this does not remove the debris of the now derelict rocket stage or satellite itself, it does substantially reduce the likelihood of the spacecraft destructing and creating many smaller pieces of space debris, a phenomenon that was common in many of the early generations of US and Soviet
SpaceX used the term "propulsive passivation" for the final maneuver of their six-hour demonstration mission (
STP-2) of the
Falcon 9 second stage for the US Air Force in 2019, but did not define what all that term encompassed. With a "one-up, one-down" launch-license policy for Earth orbits, launchers would rendezvous with, capture, and de-orbit a derelict satellite from approximately the same orbital plane. and SpaceX is developing large-scale on-orbit propellant transfer technology. Another approach to debris mitigation is to explicitly design the mission architecture to leave the rocket second-stage in an
elliptical geocentric orbit with a low-perigee, thus ensuring rapid
orbital decay and avoiding long-term orbital debris from spent rocket bodies. Such missions will often complete the payload placement in a final orbit by the use of low-thrust
electric propulsion or with the use of a small
kick stage to circularize the orbit. The kick stage itself may be designed with the excess-propellant capability to be able to self-deorbit.
Self-removal Although the ITU requires geostationary satellites to move to a graveyard orbit at the end of their lives, the selected orbital areas do not sufficiently protect GEO lanes from debris. The
Iridium constellation – 95 communication satellites launched during the five-year period between 1997 and 2002 – provides a set of data points on the limits of self-removal. The satellite operator –
Iridium Communications – remained operational over the two-decade life of the satellites (albeit with a company name change through a corporate bankruptcy during the period) and, by December 2019, had "completed disposal of the last of its 65 working legacy satellites." However, this process left 30 satellites with a combined mass of (, or nearly a third of the mass of this constellation) in LEO orbits at approximately altitude, where self-decay is slow. Of these satellites, 29 simply failed during their time in orbit and were thus unable to self-deorbit, while one – Iridium 33 – was involved in the 2009 satellite collision with the
derelict Russian military satellite
Kosmos-2251. Other proposals include a booster stage with a sail-like attachment and a large, thin, inflatable balloon envelope. In late December 2022, ESA successfully carried out a demonstration of a breaking sail-based satellite deorbiter, , which could be used by mitigation measures and is part of ESA's Zero Debris Initiative. Around one year earlier, China also tested a drag sail.
External removal A variety of approaches have been proposed, studied, or had ground subsystems built to use other spacecraft to remove existing space debris. A consensus of speakers at a meeting in Brussels, Belgium in October 2012, organized by the US think tank Secure World Foundation and the French International Relations Institute, reported that removal of the largest debris would be required to prevent the risk to spacecraft becoming unacceptable in the foreseeable future (without adding to the inventory of dead spacecraft in LEO). As of 2019, removal costs and legal questions about ownership and the authority to remove defunct satellites have stymied national or international action. Current space law retains ownership of all satellites with their original operators, even debris or spacecraft which are defunct or threaten active missions. Multiple companies made plans in the late 2010s to conduct external removal of their satellites in mid-LEO orbits. For example,
OneWeb planned to use onboard self-removal as "plan A" for satellite deorbiting at the end of life, but if a satellite were unable to remove itself within one year of end of life, OneWeb would implement "plan B" and dispatch a reusable (multi-transport mission) space tug to attach to the satellite at an already built-in capture target via a grappling fixture, to be towed to a lower orbit and released for re-entry.
Remotely controlled vehicles A well-studied solution uses a remotely controlled
vehicle to rendezvous with, capture and
detumble, and return debris to a central station. One such system is Space Infrastructure Servicing (SIS), a
commercially developed refueling depot and service spacecraft for communications satellites in geosynchronous orbit originally scheduled for a 2015 launch. The SIS would be able to "push dead satellites into graveyard orbits." The
Advanced Common Evolved Stage family of upper stages is being designed with a high leftover-propellant margin (for derelict capture and de-orbit) and
in-space refueling capability for the high
delta-v required to de-orbit heavy objects from geosynchronous orbit. A tug-like satellite to drag debris to a safe altitude for it to burn up in the atmosphere has been researched. When debris is identified the satellite creates a difference in potential between the debris and itself, then using its thrusters to move itself and the debris to a safer orbit. A variation of this approach is for the remotely controlled vehicle to rendezvous with debris,
capture it temporarily to attach a
smaller de-orbit satellite and drag the debris with a tether to the desired location. The "mothership" would then tow the debris-smallsat combination for
atmospheric entry or move it to a graveyard orbit. One such system is the proposed
Busek ORbital DEbris Remover, which would carry over 40 SUL (satellite on umbilical line) de-orbit satellites and propellant sufficient for their removal. In February 2012 the Swiss Space Center at
École Polytechnique Fédérale de Lausanne (EPFL) announced the Clean Space One project, a
nanosatellite demonstration project for matching orbit with a defunct Swiss nanosatellite, capturing it and de-orbiting together. The mission has seen several evolutions to reach a
pac-man inspired capture model. In 2013, Space Sweeper with Sling-Sat, a grappling satellite which captures and ejects debris was studied. In 2022, a Chinese satellite, SJ-21, grabbed an unused satellite and "threw" it into an orbit with a lower risk for it to collide. In December 2019, the ESA awarded the first contract to clean up space debris. The €120 million mission dubbed
ClearSpace-1 (a spinoff from the EPFL project) is slated to launch in 2026. It aims to remove the 94 kg
PROBA-1 satellite from orbit.
Laser methods The
laser broom uses a ground-based
laser to
ablate the front of the debris, producing a rocket-like thrust that slows and
detumbles the object. With continued application, the debris would fall enough to be influenced by atmospheric drag. During the late 1990s, the US Air Force's Project Orion was a laser-broom design. Although a test-bed device was scheduled to launch on a Space Shuttle in 2003, international agreements banning powerful laser testing in orbit limited its use to measurements. The 2003
Space Shuttle Columbia disaster postponed the project and according to Nicholas Johnson, chief scientist and program manager for NASA's Orbital Debris Program Office, "There are lots of little gotchas in the Orion final report. There's a reason why it's been sitting on the shelf for more than a decade." The momentum of the laser-beam
photons could directly impart a thrust on the debris sufficient to move small debris into new orbits out of the way of working satellites. NASA research in 2011 indicates that firing a laser beam at a piece of space junk could impart an impulse of per second, and keeping the laser on the debris for a few hours per day could alter its course by per day. One drawback is the potential for material degradation; the energy may break up the debris, adding to the problem. A similar proposal places the laser on a satellite in Sun-synchronous orbit, using a pulsed beam to push satellites into lower orbits to accelerate their reentry. and other proposals use a foamy ball of
aerogel or a spray of water, inflatable balloons,
electrodynamic tethers,
electroadhesion, and dedicated anti-satellite weapons.
Nets On 28 February 2014,
Japan Aerospace Exploration Agency (JAXA) launched a test "space net" satellite. The launch was an operational test only. In December 2016 the country sent a space junk collector via
Kounotori 6 to the ISS by which JAXA scientists experimented to pull junk out of orbit using a tether. The system failed to extend a 700-meter tether from a space station resupply vehicle that was returning to Earth. On 6 February the mission was declared a failure and leading researcher Koichi Inoue told reporters that they "believe the tether did not get released". Between 2012 and 2018, the ESA was working on the design of a mission to remove large space debris from orbit using mechanical tentacles or nets. The mission,
e.Deorbit, had an objective to remove debris heavier than from LEO. Several capture techniques were studied, including a net, a harpoon, and a combination robot arm and clamping mechanism., which also serve as
detumbling devices. Funding of the mission was stopped in 2018 in favor of the
ClearSpace-1 mission, which is under development.
Harpoon The
RemoveDEBRIS mission plan is to test the efficacy of several ADR technologies on mock targets in low Earth orbit. In order to complete its planned experiments, the platform is equipped with a net, a harpoon, a laser ranging instrument, a dragsail, and two
CubeSats (miniature research satellites). The mission was launched on 2 April 2018.
Recycling space debris Metal processing technologies to melt space debris and transform it into other useful form factors are developed by
CisLunar Industries. Their system uses electromagnetic heating to melt metal and shape it into metal wire, sheet metal, and metal fuel.
Reusing space debris A propulsion system dubbed the Neumann Drive has been developed in
Adelaide,
South Australia, and first sent into space in June 2023. Metal space junk is converted into
fuel rods, which can be plugged into the Neumann Drive, "basically converting the solid metal propellant into plasma". The Drive is intended to be used by American space companies which already carry nets or robotic arms to capture orbital waste. The thruster would enable these satellites to return to Earth with the waste they have collected, allowing it to be melted down to make more fuel.
Barriers to dealing with debris With the rapid development of the computer and digitalization industries, more countries and companies have engaged in space activities since the turn of the 21st century.
The tragedy of the commons is an economic theory referring to a situation where maximizing self-interest through using a shared resource can lead to the resource degradation shared by all. Based on the theory, individuals' rational action in space will lead to an irrational collective result: orbits crowded with debris. As a
common-pool resource, the Earth's orbits, especially LEO and GEO that accommodate most satellites, are
nonexcludable and
rivalrous. To address the issue and ensure
space sustainability, many technical approaches have been developed. In terms of governance mechanisms, a top-down centralized one is less suitable to tackle the complex debris problem due to the increasing number of space actors. Instead, a polycentric form of governance developed by
Elinor Ostrom has been proposed although the promotion of the polycentric network has not been fully developed.
Incomplete data of space debris As orbital debris is a global problem affecting both spacefaring and non-spacefaring nations, it is necessary to be handled in a worldwide context. To an extent, SSA plays a role in tracking space debris. In order to build a powerful SSA system, there are two prerequisites: international cooperation and exchange of information and data. Instead of joining in a coordinated way, a many SSA programs and national databases run parallel to each other with some overlaps, hindering the formation of a collaborative monitoring system. In terms of debris populations and defunct satellites, few operators have provided data. The proportion of commercial spacecraft has increased from 4.6% in the 1980s to 55.6% in the 2010s. Despite the high participation rate of commercial entities,
UN COPUOS once deliberately excluded them from having a voice in discussions unless being formally invited by a member state. The exclusion of private actors largely reduces the effectiveness of the UN committee's role in making collective-choice arrangements that reflect the interests of all space users. Ties between dissimilar stakeholders in the governance network offer access to diverse resources. Different competence among stakeholders can help allocate the tasks more reasonably. In that case, the expertise and experience of private operators are critical to help the world achieve space sustainability. For example, in 2021,
Astroscale had contracted with European and Japanese space agencies to develop the capacity of removing orbital debris. Despite that, they are still in small quantity compared to the number of those who have placed satellites in space.
Privateer Space, a Hawaiian-based startup company by American engineer
Alex Fielding, space environmentalist
Moriba Jah, and
Apple co-founder
Steve Wozniak, announced plans in September 2021 to launch hundreds of satellites into orbit in order to study space debris. However, the company stated it is in "stealth mode" and no such satellites have been launched. Besides private actors,
network governance does not necessarily exclude the states from playing a role. Instead, the different functions of states might promote the governance process. To improve the polycentric governance network of space debris, researchers suggest: encourage data-sharing among different national and organizational databases at the political level; develop shared standards for data collection systems to improve interoperability; and enhance the participation of private actors through involving them in national and international discussions. ==On other celestial bodies==