Space sustainability
Space sustainability aims to maintain the safety and health of the space environment.[1]
Similar to sustainability initiatives on Earth, space sustainability seeks to use the environment of space to meet the current needs of society without compromising the needs of future generations.[2][3][4] It usually focuses on space closest to Earth, Low Earth Orbit (LEO), since this environment is the one most used and therefore most relevant to humans.[5] It also considers Geostationary Equatorial Orbit (GEO) as this orbit is another popular choice for Earth-orbiting mission designs.[6]
The issue of space sustainability is a new phenomenon that is gaining more attention in recent years as the launching of satellites and other space objects has increased.[7] These launches have resulted in more space debris orbiting Earth, hindering the ability of nations to operate in the space environment while increasing the risk of a future launch-related accident that could disrupt its proper use.[8][9] Space weather also acts as an outstanding factor for spacecraft failure.[6] The current protocol for spacecraft disposal at end-of-life has, at large, not been followed in mission designs and demands extraneous amounts of time for disposal.[10][11]
Precedent created through prior policy initiatives has facilitated initial mitigation of space pollution and created a foundation for space sustainability efforts.[10] To further mitigation, international and transdisciplinary consortia have stepped forward to analyze existing operations, develop standards, and incentivize future procedures to prioritize a sustainable approach.[12] A shift towards sustainable interactions with the space environment is growing in urgency due to the implications of climate change and increasing risk to spacecraft as time presses on.[11][13]
Current state[]
Space sustainability comes into play to address the pressing current state of near-Earth orbits and its high amounts of orbital debris.[14] Spacecraft collisions with orbital debris, space weather, overcrowding in low earth orbit (LEO) makes spacecraft susceptible to higher rates of failure.[14][11] The current end-of-life protocol for spacecraft exacerbates the space sustainability crisis; many spacecraft are not properly disposed, which increasing the likelihood of further collisions.[14]
Orbital debris[]
Orbital debris is defined as unmanned, inoperate objects that exist in space.[15] This orbital debris breaks down further as time progresses as a result of naturally occurring events, such as high-velocity collisions with micrometeoroids, and forced events, such as a controlled release of a launch vehicle.[15] In LEO, these collisions can take place at speeds anywhere between an average velocity of 9 kilometers per second (km/s) and 14 km/s relative to the debris and spacecraft.[15] In GEO, however, these high-speed collisions are a much lower risk as the average relative velocity between the debris and spacecraft is typically between 0 km/s and 2.5 km/s.[15] As of 2012, the United States Joint Space Operations Center tracked 21,000 pieces of orbital debris larger than 10 cm in Earth’s nearby orbits (LEO, GEO, and sun-synchronous), where 16,000 of these pieces are catalogued. Space debris can be categorized into three categories: small, medium, and large.[14] Small debris is for pieces that are less than 10 centimeters (cm).[14] Medium-sized debris is for pieces larger than 10 cm, but not an entire spacecraft.[14] Large-sized debris has no official classification, but typically refers to entire spacecraft, such as an out of use satellite or launch vehicle.[14] It is difficult to track small-sized debris in LEO, and challenging to track small and medium-sized debris in GEO.[15] Yet this statement is not to discount the abilities of LEO and GEO tracking capabilities, the smallest piece of tracked debris can weigh as low as ten grams.[15] If the size of the debris prohibits it from being tracked, it also cannot be avoided by the spacecraft and does not allow the spacecraft to lower its risk of collisions.[15] The likelihood of the Kessler syndrome, which essentially states that each collision produces more debris, grows larger as the amount of orbital debris multiplies, increasing the amount of further collisions until space cannot be used entirely.[14]
Space weather[]
Space weather poses a risk to satellite health, consequently, resulting in greater amounts of orbital debris.[6] Space weather impacts satellite health in a variety of ways. Firstly, surface charging from the sun’s surface facilitates electrical discharges, damaging on-orbit electronics, posing a threat to mission failure.[6] Single Event Upsets (SEUs) can also damage electronics.[6] Dielectric charging and bulk charging can also occur, causing energy problems within the spacecraft.[6] Additionally, at altitudes less than one thousand kilometers, atmospheric drag can increase during solar storms by increasing the altitude of the spacecraft, only adding more drag onto the spacecraft.[6] These factors degrade performance over the spacecraft’s lifetime, leaving the spacecraft more susceptible to further system and mission failures.[6]
Overcrowding[]
There has been a dramatic increase in the use of LEO and GEO orbits over the last sixty years since the first satellite launch in 1957. To date, there have been approximately ten thousand satellite launches, whereas only approximately 2000 are still active.[14] These satellites can be used for a variety of purposes, which are telecommunications, navigation, weather monitoring, and exploration. Within the coming decade, companies like SpaceX are predicted to launch an additional fifteen thousand satellites into LEO and GEO orbits.[14] Microsatellites built by universities or research organizations have also increased in popularity, contributing to the overcrowding of near earth orbits.[11] This overcrowding of LEO and GEO orbits increases the likelihood of potential collisions among satellites and orbital debris, contributing further to the large amount of orbital debris present in space.[14]
End of life protocol[]
The current end of life protocol is that at the end of mission, spacecraft are either added to the graveyard orbit or at a low enough altitude that drag will allow the spacecraft to burn up upon reentry and fall back to Earth.[11] Approximately twenty satellites are put into the graveyard orbit each year, but this rate is expected to increase to one thousand satellites per year by 2050.[11] There is no current process to return satellites to Earth after entering the graveyard orbit.[14] The process of a spacecraft returning to Earth via drag can take between ten to one hundred years.[14] This protocol is critical to reduce overcrowding in near-Earth orbits.[14]
Regulations[]
Current space sustainability efforts rely heavily on the precedent set by regulatory agreements and conventions of the twentieth century.[10] Much of this precedent is included in or is related to the Outer Space Treaty of 1963, which represented one of the initial major efforts by the United Nations to create legal frameworks for the operation of nations in space.[16]
Pre-Outer Space Treaty[]
The international community has had concerns about space contamination since the 1950’s prior to the launch of Sputnik I.[17] These concerns stemmed from the idea that increasing rates of exploration into further areas of outer space could lead to contamination capable of damaging other planetary bodies, resulting in limitations to human exploration on these bodies and potential harm to the Earth.[17]Efforts to combat these concerns began in 1956 with the International Astronautical Federation (IAF) and the United Nations Committee on the Peaceful Uses of Outer Space (COPUOUS). These efforts continued to 1957 through the National Academy of Sciences and International Council for Science (ICSU).[17] Each of these organizations aimed to study space contamination and develop strategies for how to best address its potential consequences.[17] The ICSU went on to create the Committee on Contamination by Extraterrestrial Exploration (CETEX) that put forward recommendations leading to the establishment of the Committee on Space Research (COSPAR).[17] COSPAR continues to address outer space research on an international scale today [cite cospar].
Outer Space Treaty[]
Relevant regulations of international space law to sustainability in space can be found in the Outer Space Treaty, which was adopted by the UN General Assembly in 1963.[18] The Outer Space Treaty contains seventeen articles designed to create a basic framework for how international law can be applied in outer space.[16] Basic principles of the Outer Space Treaty include the provision in Article IX that parties should "avoid harmful contamination of space and celestial bodies;" [16] definitions of "harmful contamination" are not provided.[19][16] Other articles of relevance to space sustainability include articles I, II, and III that concern the fair and inclusive international use of space in a manner free from sovereignty, ownership, or occupation by any nation.[16] In addition, articles VII and VIII protect ownership by their respective countries of any objects launched to space while attributing responsibility for any damages to the property or personnel of other countries by those objects to said countries. [16] Descriptions or definitions for what these damages may entail are not provided.[16]
COSPAR Planetary Protection Policy[]
Principles of Article IX provided the basis for the Committee of Space Research (COSPAR) Planetary Protection Policy guidelines, which are generally well-regarded among scientific experts.[20] Such guidelines, however, are non-binding and often described as "soft-law," as they lack legal mandate.[21] The Planetary Protection Policy is primarily concerned with providing information regarding best practices to avoid contamination of the space environment during space exploration missions.[22] COSPAR believes that the prevention of such contamination is in the best interest of humanity as it may impede scientific progress, exploration, and the mission of a search for life.[22] In addition, the argument is made that cross-contamination of the Earth can be potentially harmful to its environment due to the largely unknown nature of potential space contaminants.[22]
Other relevant regulations[]
Regulatory clarifications concerning the Outer Space Treaty of 1963 of relevance to space sustainability were made in subsequent years. The 1967 Return Agreement relates mainly to the return of lost astronauts to their appropriate nations, but also requires Outer Space Treaty signing nations to assist other nations with the return of objects that return to Earth from orbit to their proper owners[23] The 1972 Liability Convention attributes liability for damages from space objects to the nation that launched the object, regardless of whether that damage occurred in space or on Earth.[24] Other clarifications include the 1975 registration convention that attempted to create mechanisms for nations to identify space objects, and the 1979 Moon Agreement that established protections for the environments of the Moon and other nearby planetary bodies.[25][26] These agreements and conventions represented attempts to improve the initial Outer Space Treaty as space exploration continued to grow in importance throughout the 20th century.[17]
Mitigation[]
Sustainability mitigation efforts include but are not limited to design specifications, policy change, removal of space debris, and restoration of orbiting semi-functional technologies.[14][27][12][28] Efforts begin by regulating the debris released during normal operations and post-mission breakups [6]. Due to the increased awareness of high-velocity collisions and orbital debris in the previous decades, missions have adapted design specifications to account for these risks.[15] For example, the RADARSAT program implemented 17 kilograms of shielding to their spacecraft, which increased the program’s predicted success rate to 87% from 50%.[15] Another effort in mitigation is restoring semi-functional satellites, which allows a spacecraft classified as “debris” to “functional.” [10] Space debris mitigation focuses on limiting debris release during normal operations, collisions and intentional destruction.[14] Mitigation also includes reducing the possibility for post-mission breakups due to stored energy and/or operations phases, as well as addressing procedure for end of mission disposal for spacecraft.[14]
Space Sustainability Rating[]
One example leading the regulatory sustainability measures is the Space Sustainability Rating (SSR), which is an instigator for industry competitors to incorporate sustainability into spacecraft design.[12] The Space Sustainability Rating was first conceptualized at the World Economic Forum Global Future Council on Space Technologies designed by international and transdisciplinary consortia.[12] The four leading organizations are the European Space Agency, Massachusetts Institute of Technology, University of Texas at Austin, and BryceTech with the goal to define the technical and programmatic aspects of the SSR.[27] The SSR represents an innovative approach to combating orbital debris through incentivizing the industry to prioritize sustainable and responsible operations.[12] This response entails the consideration of potential harm to the space environment and other spacecraft, all while maintaining mission objectives and high-quality service.[27] The rating takes inspiration from other standards, like leadership in energy and environmental design (LEED) for the building sector. Several of the factors emphasized in the rating were extracted from LEED design considerations like the incorporation of feedback and public comments, or the rating’s advocacy to influence policy, such as orbit fragmentation risks, collision avoidance capabilities, trackability, and adoption of international standards.[12]
Tracking[]
Tracking is one of the main Space Sustainability Rating modules’ efforts. The module "Detectability, Identification and Tracking" (DIT) consists of standardizing the comparison of satellite missions to encourage satellite operators to improve their satellite design and operational approaches for the observer to detect, identify, and track the satellites.[12] Tracking presents challenges when the observer seeks to monitor and predict the spacecraft behavior over time.[27] While the observer may know the name, owner, and instantaneous location of the satellite, the operator controls the full knowledge of the orbital parameters. [27] The Space Situational Awareness (SSA) is one the tools geared towards solving the challenges presented when tracking orbiting satellites and debris.[14] The SSA continuously tracks objects using ground-based radar and optical stations so the orbital paths of debris can be predicted and operations avoid collisions.[14] It feeds data to 30 different systems like satellites, optical telescopes, radar systems, and supercomputers to predict risk of collision days in advance.[14] Other efforts in tracking orbital debris are made by the US Space Surveillance Network (SSN).[15]
Removal[]
Under the "External Services" module of the SSR, the rating offers commitment to use or demonstration of use of end-of-life removal services.[12] Space debris mitigation measures are found to be inadequate to stabilize debris environments with an actual current compliance of approximately sixty percent.[14] Moreover, a low compliance rate of approximately thirty percent of the 103 spacecraft that reached end of life between 1997 and 2003 were disposed of in a graveyard orbit.[14] Since policy has not caught up to ensure the longevity of LEO for future generations, actions like Active Debris Removal (ADR) are being considered to stabilize the future of LEO environment.[14] Most famous removal concepts are based on directed energy, momentum exchange or electrodynamics, aerodynamic drag augmentation, solar sails, auxiliary propulsion units, retarding surfaces and on-orbit capture.[14] As ADR consists of an external disposal method to remove obsolete satellites or spacecraft fragments.[13] Since large-sized debris objects in orbit provide a potential source for tens of thousands of fragments in the future, ADR efforts focus on objects with high mass and large cross-sectional areas, in densely populated regions, and at high altitudes; in this instance, retired satellites and rocket bodies are a priority.[14] Other practical advancements toward space debris removal include missions like RemoveDEBRIS and End-of-Life Service (ELS-d).[14]
Growing Urgency[]
The previous reduced state of regulation and mitigation on space debris[11] and rocket fuel emissions[28] is aggravating the Earth’s stratosphere through collisions and ozone depletion, increasing the risk for spacecraft health through its lifetime.
Inaccessibility to LEO[]
Due to the increase of satellites being launched and the growing amount of orbital debris in LEO,[14] the risk of LEO becoming inaccessible over time (in accordance with the Kessler syndrome) is increasing in likelihood. The mitigation policies for creating space debris fall under an area of voluntary codes by the states, although it has been disputed whether the Article I Outer Space Treaty or the Article IX Outer Space Treaty protects the space environment from deliberate harm, which has yet to be upheld.[11] In 2007, an inactive Chinese satellite was purposefully destroyed by the Chinese government as a part of their anti-satellite weapon test (ASAT), spreading nearly 2800 objects of space debris five centimeters or larger into LEO.[29] An analysis concluded that about eighty percent of the debris will remain in LEO nine years after this destruction.[29] In addition, the destruction increased the collision likelihood for three Italian satellites that launched the same year as the Fengyun-1C destruction.[29] The increase in collision ranged between ten and sixty percent.[29] However, there were no legal consequences against the Chinese government.[29]
Rocket fuel emissions[]
When rockets are launched into space, parts of their fuel enter the stratosphere of the Earth. Rocket fuel emissions are made up of carbon dioxide, water, hydrochloric acid, alumina and soot particles. The most concerning emissions from rocket fuel are chlorine and alumina particles from solid rocket motors (SRMs) and soot from kerosene fueled engines. When the hydrochloric acid from the engine exhaust dissociates, the free chlorine roams freely in the stratosphere.[30] The chemical reaction between these chlorine and alumina causes ozone depletion. In addition, the soot particles form over a black umbrella over the stratosphere which can cause the temperature of the Earth’s surface to lower and further depleting the ozone layer, an unintentional form of geoengineering.[28] The nature of geoengineering has been disputed as a form of mitigating global warming and has the possibility of being banned and holding rockets accountable for the soot particles they distribute to the stratosphere. New types of engines and fuels are emerging, mainly the liquid oxygen (LOX) and monomethylhydrazine engine, but there is minimal research on their impact on the environment besides their emission of hydroxide and nitrogen oxide compounds, two molecules that have significant impact on the ozone layer.[28] Currently, rocket fuel emissions have been deemed insignificant when it comes to their consequences to Earth’s environment and LEO.[28] However, emissions will increase in the coming years, making rocket fuel’s contribution to global warming much more significant.
See also[]
- Common heritage of humanity
- Graveyard orbit
- Human presence in space
- Kessler syndrome
- List of space debris producing events
- Rights of nature
- Satellite collision
- Spacecraft cemetery
- Space debris
- Space law
References[]
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- Space debris
- Global issues
- Space hazards
- Near-Earth objects
- Future problems
- Pollution