List of objects at Lagrange points#Earth–Moon Lagrange points

{{L1}} is the Lagrange point located approximately 1.5 million kilometers from Earth towards the Sun.

• International Cometary Explorer, formerly the International Sun–Earth Explorer 3 (ISEE-3), diverted out of {{L1}} in 1983 for a comet rendezvous mission. Currently in heliocentric orbit. The Sun–Earth L₁ is also the point to which the Reboot ISEE-3 mission was attempting to return the craft as the first phase of a recovery mission (as of September 25, 2014 all efforts have failed and contact was lost)."ISEE-3 is in Safe Mode". Space College. 25 September 2014. "The ground stations listening to ISEE-3 have not been able to obtain a signal since Tuesday the 16th"
• NASA's Genesis probe collected solar wind samples at {{L1}} from December 3, 2001, to April 1, 2004, when it returned the sample capsule to Earth. It returned briefly in late 2004 before being pushed into heliocentric orbit in early 2005.
• LISA Pathfinder (LPF) was launched on 3 December 2015, and arrived at {{L1|nolink=yes}} on 22 January 2016, where, among other experiments, it tested the technology needed by (e)LISA to detect gravitational waves. LISA Pathfinder used an instrument consisting of two small gold alloy cubes.
• The Chang'e 5 orbiter{{cite web|title=Chang'e 5 Test Mission Updates|url=http://www.spaceflight101.com/change-5-test-mission-updates.html|website=Spaceflight 101|access-date=14 December 2014}} (during extended mission. After ferrying lunar samples back to Earth in 2020, the transport module was sent to {{L1|nolink=yes}} where it is permanently stationed to conduct limited Earth-Sun observations.)

• The Solar and Heliospheric Observatory (SOHO) in a halo orbit around L1
• Mission: Investigation of the outer layer of the Sun, making observations of solar wind and associated phenomena in the vicinity of L1, probing the interior structure of the Sun.
• Launched: 2 December 1995
• Arrival: Operational orbit in May 1996
• Institution: 15px ESA
• The Advanced Composition Explorer (ACE) in a Lissajous orbit
• WIND (At {{L1}} since 2004)

File:Animation of Deep Space Climate Observatory trajectory.gif }}{{·}}{{legend2|RoyalBlue|Earth}}{{·}}{{legend2|yellow|Moon}}]]

• The Deep Space Climate Observatory (DSCOVR), designed to image the sunlit Earth in 10 wavelengths (EPIC) and monitor total reflected radiation (NISTAR). Launched on 11 February 2015, began orbiting L₁ on 8 June 2015 to study the solar wind and its effects on Earth.{{cite web|url=http://www.nesdis.noaa.gov/news_archives/DSCOVR_L1_orbit.html|title=NOAA's Satellite and Information Service (NESDIS)|author=US Department of Commerce, NOAA Satellites and Information Service|url-status=dead|archive-url=https://web.archive.org/web/20150608182042/http://www.nesdis.noaa.gov/news_archives/DSCOVR_L1_orbit.html|archive-date=2015-06-08}} DSCOVR is unofficially known as GORESAT, because it carries a camera always oriented to Earth and capturing full-frame photos of the planet similar to the Blue Marble. This concept was proposed by then-Vice President of the United States Al Gore in 1998{{cite web|url=https://www.usatoday.com/story/tech/2015/02/07/goresat-gore-satellite-deep-space-climate/23013283/|title=At long last: Al Gore's satellite dream blasts off|date=7 February 2015|work=USA TODAY}} and was a centerpiece in his 2006 film An Inconvenient Truth.Mellow, Craig (August 2014). "Al Gore's Satellite". Air & Space/Smithsonian. Retrieved December 12, 2014.
• Aditya-L1 was successfully launched on 2 September 2023 and entered the halo orbit around the lagrange point on 6 January 2024.{{cite web |last=Kumar |first=Chethan |url=https://timesofindia.indiatimes.com/home/science/aditya-reaches-halo-orbit-around-l1-point-sun-study-to-begin-soon/articleshow/106594444.cms?from=mdr |title=Aditya reaches halo orbit around L1 point, Sun study to begin soon |date=6 January 2024 |access-date=6 January 2024 |work=The Times of India}} It's a Solar observation mission by ISRO. It will study solar atmosphere, solar magnetic storms, and their impact on the environment around the Earth.{{Cite web |date=2 September 2023 |title=Aditya L1 Mission: Aditya L1 Launch LIVE Updates: Aditya L1 spacecraft successfully separated from PSLV rocket, now en route to Sun-Earth L1 point. ISRO says mission accomplished |url=https://economictimes.indiatimes.com/news/newsblogs/aditya-l1-live-news-updates-isro-first-solar-mission-launch-02-september-2023/liveblog/103297403.cms |url-status=live |archive-url=https://web.archive.org/web/20230903115715/https://economictimes.indiatimes.com/news/newsblogs/aditya-l1-live-news-updates-isro-first-solar-mission-launch-02-september-2023/liveblog/103297403.cms |archive-date=3 September 2023 |access-date=2 September 2023 |website=The Economic Times |language=en}}

• Interstellar Mapping and Acceleration Probe slated for launch in late 2025
• NEO Surveyor
• SWFO-L1
• Vigil (ESA). One spacecraft in L1 and one in L5.

{{anchor|Sun-Earth L2}}{{L2}} is the Lagrange point located approximately 1.5 million kilometers from Earth in the direction opposite the Sun. Spacecraft at the Sun–Earth L₂ point are in a Lissajous orbit until decommissioned, when they are sent into a heliocentric graveyard orbit.{{citation needed|date=January 2022|reason=moved here from Lagrange point and kept because it was uncontested there, but it's a general claim that should be referenced.}}

File:Animation of Wilkinson Microwave Anisotropy Probe trajectory.gif }}{{·}}{{legend2|RoyalBlue|Earth}}]]

• 2001 – 2010: NASA's Wilkinson Microwave Anisotropy Probe (WMAP){{cite web | title=Mission Complete! WMAP Fires Its Thrusters For The Last Time | url=http://news.discovery.com/space/mission-complete-wmap-fires-its-thrusters-for-the-last-time.html | access-date=2022-01-11 | archive-date=2012-07-14 | archive-url=https://web.archive.org/web/20120714021615/http://news.discovery.com/space/mission-complete-wmap-fires-its-thrusters-for-the-last-time.html | url-status=dead }} observed the cosmic microwave background. It was moved to a heliocentric orbit to avoid posing a hazard to future missions.
• 2003 – 2004: NASA's WIND. The spacecraft then went to Earth orbit, before heading to {{L1}}.{{cite web|url=https://directory.eoportal.org/web/eoportal/satellite-missions/v-w-x-y-z/wind#mission-status|title=WIND Solar-Terrestrial Mission|publisher=ESA Earth Observation Portal|access-date=December 31, 2021}}
• 2009 – 2013:{{cite news|url=http://www.huffingtonpost.com/2013/06/19/herschel-telescope-shut-down-esa_n_3461962.html|title=Herschel Space Telescope Shut Down For Good, ESA Announces | work=Huffington Post | first=Adam|last=Toobin|date=2013-06-19}} The ESA Herschel Space Observatory exhausted its supply of liquid helium and was moved from the Lagrangian point in June 2013.
• 2009 – 2013: At the end of its mission ESA's Planck spacecraft was put into a heliocentric orbit and passivated to prevent it from endangering any future missions.
• 2011 – 2012: CNSA's Chang'e 2.{{Cite web|url=http://articles.economictimes.indiatimes.com/2011-08-30/news/29945291_1_chang-e-2-china-s-moon-moon-landing|archive-url=https://web.archive.org/web/20120523190602/http://articles.economictimes.indiatimes.com/2011-08-30/news/29945291_1_chang-e-2-china-s-moon-moon-landing|url-status=dead|archive-date=May 23, 2012|title=China's Moon orbiter Chang'e-2 travels 1.5 km into outer space|date=2011-08-30|access-date=2011-08-31|publisher=The Economic Times}}{{cite web|url=http://www.planetary.org/blogs/emily-lakdawalla/2012/06150926-change2-update.html|title=Update on yesterday's post about Chang'e 2 going to Toutatis|publisher=Planetary Society|date=15 June 2012|access-date=26 June 2012|last=Lakdawalla|first=Emily| author-link = Emily Lakdawalla}} Chang'e 2 was then placed onto a heliocentric orbit that took it past the near-Earth asteroid 4179 Toutatis.
• The CNSA Chang'e 6 orbiter
• 2013 – 2025: The ESA Gaia mission’s thrusters moved the spacecraft away from L2 on 27 March 2025 and into a stable retirement orbit around the Sun that will minimise the chance that it comes within 10 million km Earth for at least the next century.

File:The orbits of Gaia and Webb ESA23998736.png and James Webb Space Telescope orbit around Sun-Earth {{L2|nolink=yes}}]]

• The joint Russian-German high-energy astrophysics observatory Spektr-RG
• The joint NASA, ESA and CSA James Webb Space Telescope (JWST)
• The ESA Euclid mission

• The NASA Nancy Grace Roman Space Telescope (WFIRST)
• The ESA PLATO mission, which will find and characterize rocky exoplanets.
• The JAXA LiteBIRD mission.
• The ESA Advanced Telescope for High ENergy Astrophysics (ATHENA)
• The ESA ARIEL mission, which will observe the atmospheres of exoplanets.
• The joint ESA-JAXA Comet Interceptor
• The NASA Large Ultraviolet Optical Infrared Surveyor (LUVOIR) which would replace the Hubble Space Telescope.

• The ESA Eddington mission
• The NASA Terrestrial Planet Finder mission (may be placed in an Earth-trailing orbit instead)

{{L3}} is the Sun–Earth Lagrange point located on the side of the Sun opposite Earth, slightly outside the Earth's orbit. Direct communication with spacecraft in this position is blocked by the Sun.

• There are no known objects in this orbital location. {{Citation Needed|date=June 2024}}

{{L4}} is the Sun–Earth Lagrange point located close to the Earth's orbit 60° ahead of Earth.

• Asteroid {{mpl|(706765) 2010 TK|7}} is the first discovered tadpole orbit companion to Earth, orbiting {{L4}}; like Earth, its mean distance to the Sun is about one astronomical unit.
• Asteroid {{mpl|(614689) 2020 XL|5}} is the second Earth trojan, confirmed in November 2021, oscillating around {{L4|nolink=yes}} in a tadpole orbit and expected to remain there for at least 4000 years, until destabilized by Venus.{{cite journal

|first1 = Man-To |last1 = Hui

|first2 = Paul A. |last2 = Wiegert

|first3 = David J. |last3 = Tholen

|first4 = Dora |last4 = Föhring

|title = The Second Earth Trojan 2020 XL5

|journal = The Astrophysical Journal Letters

|date = November 2021

|volume = 922

|issue = 2

|pages = L25

|doi = 10.3847/2041-8213/ac37bf

|arxiv = 2111.05058

|bibcode = 2021ApJ...922L..25H

|s2cid = 243860678

|doi-access = free

}}

• STEREO A (Solar TErrestrial RElations Observatory – Ahead) made its closest pass to {{L4|nolink=yes}} in September 2009, on its orbit around the Sun, slightly faster than Earth.[http://www.nasa.gov/mission_pages/stereo/news/gravity_parking.html NASA - Join STEREO and Explore Gravitational "Parking Lots" That May Hold Secret of Moon's Origin]
• OSIRIS-REx passed near the L4 point and performed a survey for asteroids between 9 and 20 February 2017.

{{L5}}, or Earth-trailing orbit, is the Sun–Earth Lagrange point located close to the Earth's orbit 60° behind Earth.

• Asteroid {{mpl|419624|2010 SO|16}}, in a horseshoe companion orbit with Earth, is currently proximal to {{L5}} but at a high inclination.
• STEREO B (Solar TErrestrial RElations Observatory – Behind) made its closest pass to {{L5|nolink=yes}} in October 2009, on its orbit around the Sun, slightly slower than Earth.
• The Spitzer Space Telescope is in an Earth-trailing heliocentric orbit drifting away c. 0.1 AU per year. In c. 2013–15 it has passed {{L5}} in its orbit.
• Hayabusa2 passed near {{L5}} during the spring of 2017, and imaged the surrounding area to search for Earth trojans on 18 April 2018.{{cite web |url=http://www.hayabusa2.jaxa.jp/topics/20170823/ |title=太陽−地球系のL5点付近の観測の結果について |publisher=JAXA |date=23 August 2017 |access-date=2018-06-22 |language=ja}}

• Vigil (ESA). One spacecraft in L5.

• THEMIS
• Chang'e 5-T1
• Queqiao relay satellite
• EQUULEUS nanosat.

• Kordylewski clouds{{cite journal |last1=Slíz-Balogh |first1=Judith |last2=Barta |first2=András |last3=Horváth |first3=Gábor |title=Celestial mechanics and polarization optics of the Kordylewski dust cloud in the Earth–Moon Lagrange point L5 – I. Three-dimensional celestial mechanical modelling of dust cloud formation |date=11 November 2018 |journal=Monthly Notices of the Royal Astronomical Society |volume=480 |issue=4 |pages=5550–5559 |doi=10.1093/mnras/sty2049 |doi-access=free |arxiv=1910.07466 |bibcode=2018MNRAS.480.5550S }}
• Future location of TDRS-style communication satellites to support {{L2}} satellite and further regions on the Moon.{{cite magazine |last=Hornig |first=Andreas |title=TYCHO: Supporting Permanently Crewed Lunar Exploration with High-Speed Optical Communication from Everywhere |url=https://ideas.esa.int/servlet/hype/IMT?userAction=Browse&templateName=&documentId=e3f5e00bb992b91a4378e46176b02376 |magazine=ESA |date=2022-05-01}}{{cite magazine |last=Hornig |first=Andreas |title=TYCHO mission to Earth-Moon libration point EML-4 @ IAC 2013 |url=https://www.youtube.com/watch?v=7RJSLFP7yyA |magazine=IAC2013 |date=2013-10-06}}

• Hiten was the first spacecraft to demonstrate a low energy trajectory, passing by {{L4}} and {{L5}} to achieve lunar orbit at a very low fuel expense, compared to usual orbital techniques. Hiten did not find any conclusive increase in dust density at Lagrange points."[https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1990-007A Hiten]", NSSDC.GSFC.NASA.gov.

• Exploration Gateway Platform
• In his 1976 book The High Frontier: Human Colonies in Space Dr. Gerard O'Neill proposed the establishment of gigantic Space Islands in {{L5}}. The inhabitants of the L5 Society should convert lunar material to huge solar power satellites. Many works of fiction, most notably the Gundam series, involve colonies at these locations.

• {{mpl|2013 ND|15}}

Asteroids in the {{L4}} and {{L5}} Sun–Mars Lagrangian points are sometimes called Mars trojans, with a lower-case t, as "Trojan asteroid" was originally defined as a term for Lagrangian asteroids of Jupiter. They may also be called Mars Lagrangian asteroids.

• {{mpl|(121514) 1999 UJ|7}}

• 5261 Eureka
• {{mpl|(101429) 1998 VF|31}}
• {{mpl|(311999) 2007 NS|2}}
• {{mpl|(385250) 2001 DH|47}}, {{mpl|2001 FG|24}}, {{mpl|(461377) 2001 FR|127}} (not confirmed as true Lagrangian asteroids)

Source: Minor Planet Center [http://www.minorplanetcenter.org/iau/lists/MarsTrojans.html]

• 1372 Haremari
• {{mpl|76146|2000 EU|16}}
• {{mpl|185105|2006 SV|23}}

Asteroids in the {{L4}} and {{L5}} Sun–Jupiter Lagrangian points are known as Jupiter Trojan asteroids or simply Trojan asteroids.

• Trojan asteroids, Greek camp

• Trojan asteroids, Trojan camp

• Lucy (spacecraft), L4 in 2027, L5 in 2033

• Telesto

• Calypso

• Helene

• Polydeuces, follows a "tadpole" orbit around L₅

• 83982 Crantor, follows a horseshoe orbit around L₃

• {{mpl|(687170) 2011 QF|99}}{{cite journal | arxiv=1303.5774 | doi=10.1126/science.1238072 | title=A Uranian Trojan and the Frequency of Temporary Giant-Planet Co-Orbitals | date=2013 | last1=Alexandersen | first1=Mike | last2=Gladman | first2=Brett | last3=Greenstreet | first3=Sarah | last4=Kavelaars | first4=J. J. | last5=Petit | first5=Jean-Marc | last6=Gwyn | first6=Stephen | journal=Science | volume=341 | issue=6149 | pages=994–997 | pmid=23990557 | bibcode=2013Sci...341..994A }}
• {{mpl|(636872) 2014 YX|49}}

Minor planets in the {{L4}} and {{L5}} Sun–Neptune Lagrangian points are called Neptune trojans, with a lower-case t, as "Trojan asteroid" was originally defined as a term for Lagrangian asteroids of Jupiter.

Data from: Minor Planet Center [http://www.minorplanetcenter.org/iau/lists/NeptuneTrojans.html]

• 385571 Otrera
• 385695 Clete
• {{mpl|(612243) 2001 QR|322}}
• {{mpl|2005 TN|53}}
• {{mpl|(613490) 2006 RJ|103}}
• {{mpl|(527604) 2007 VL|305}}

• {{mpl|2008 LC|18}}
• {{mpl|2004 KV|18}}
• {{mpl|2011 HM|102}}

Color key:

{{legend inline|#FFFFFF|Unflown or planned mission}}

{{legend inline|#F2F2F2|Mission en route or in progress (including mission extensions)}}

{{legend inline|#CCFFD9|Mission at Lagrangian point completed successfully (or partially successfully)}}

{{sticky header}}

|- style="background:#F2F2F2"

!scope=row| WIND

| Sun–Earth {{L1|nolink=yes}} || NASA || Arrived at L₁ in 2004 with fuel for 60 years. Operational {{as of|2019|lc=y|}}.{{Cite web|url=http://www.nasa.gov/feature/goddard/2019/25-years-of-science-in-the-solar-wind|title=25 Years of Science in the Solar Wind|last=Tran|first=Lina|date=2019-10-31|website=NASA|access-date=2020-02-12}}

|- style="background:#CCFFD9"

!scope=row| Wilkinson Microwave Anisotropy Probe (WMAP)

| Sun–Earth {{L2|nolink=yes}} || NASA || Arrived at L₂ in 2001. Mission ended 2010,{{cite web| url=http://map.gsfc.nasa.gov/news/facts.html | title=WMAP Facts | publisher=NASA | access-date=2013-03-18 }} then sent to solar orbit outside L₂.http://map.gsfc.nasa.gov/news/events.html WMAP Ceases Communications

|- style="background:#CCFFD9"

!scope=row| Herschel Space Telescope

| Sun–Earth {{L2|nolink=yes}} || ESA

| Arrived at L₂ July 2009. Ceased operation on 29 April 2013; will be moved to a heliocentric orbit.{{cite web|url=http://www.esa.int/esaSC/SEMA539YFDD_index_0.html |title=Herschel Factsheet |publisher=European Space Agency |access-date=2009-05-12 |date=17 April 2009}}{{cite news | url = https://www.bbc.co.uk/news/science-environment-21934520 | work = BBC News | title =Herschel space telescope finishes mission | date = 29 April 2013}}

|- style="background:#CCFFD9"

!scope=row| Planck Space Observatory

| Sun–Earth {{L2|nolink=yes}} || ESA

| Arrived at L₂ July 2009. Mission ended on 23 October 2013; Planck has been moved to a heliocentric parking orbit.{{cite web|title=Last command sent to ESA's Planck space telescope|url=http://www.esa.int/Our_Activities/Space_Science/Planck/Last_command_sent_to_ESA_s_Planck_space_telescope|publisher=European Space Agency|date=October 23, 2013|access-date=October 23, 2013}}

|- style="background:#CCFFD9"

!scope=row|Chang'e 2

| Sun–Earth {{L2|nolink=yes}} || CNSA

| Arrived in August 2011 after completing a lunar mission before departing en route to asteroid 4179 Toutatis in April 2012.

|- style="background:#CCFFD9"

!scope=row| ARTEMIS mission extension of THEMIS

| Earth–Moon {{L1|nolink=yes}} and {{L2|nolink=yes}} || NASA || Mission consists of two spacecraft, which were the first spacecraft to reach Earth–Moon Lagrangian points. Both moved through Earth–Moon Lagrangian points, and are now in lunar orbit.{{cite web|last=Fox|first=Karen C.|title=First ARTEMIS Spacecraft Successfully Enters Lunar Orbit|url=http://www.nasa.gov/mission_pages/artemis/news/P1-lunarOrbit.html|work=The Sun-Earth Connection: Heliophysics|date=25 March 2015 |publisher=NASA}}{{cite web|last=Hendrix|first=Susan|title=Second ARTEMIS Spacecraft Successfully Enters Lunar Orbit|url=http://www.nasa.gov/mission_pages/artemis/news/P2-lunarOrbit.html|work=The Sun-Earth Connection: Heliophysics|date=25 March 2015 |publisher=NASA}}

|- style="background:#CCFFD9"

!scope=row| WIND

| Sun–Earth {{L2|nolink=yes}} || NASA || Arrived at L₂ in November 2003 and departed April 2004.

|- style="background:#CCFFD9"

!scope=row| Gaia Space Observatory

| Sun–Earth {{L2|nolink=yes}} || ESA || Launched 19 December 2013.{{cite web|url=http://www.spaceflightnow.com/tracking/index.html |title=Worldwide launch schedule |publisher=Spaceflight Now |date=27 November 2013 |url-status=dead |archive-url=https://web.archive.org/web/20100530232910/http://www.spaceflightnow.com/tracking/index.html |archive-date= 30 May 2010 }} Operational {{As of|2020||lc=y}}.{{Cite web|url=https://sci.esa.int/web/gaia/-/47354-fact-sheet|title=ESA Science & Technology - Fact Sheet|website=sci.esa.int|access-date=2020-02-12}}

|- style="background:#CCFFD9"

!scope=row| Chang'e 5-T1 Service Module

| Earth–Moon {{L2|nolink=yes}} || CNSA || Launched on 23 October 2014, arrived at L₂ halo orbit on 13 January 2015.

|- style="background:#CCFFD9"

!scope=row| Queqiao

| Earth–Moon {{L2|nolink=yes}} || CNSA || Launched on 21 May 2018, arrived at L₂ halo orbit on June 14 for Chang'e 4 mission.{{cite web |url=https://gbtimes.com/china-launches-queqiao-relay-satellite-to-support-change-4-lunar-far-side-landing-mission |title=China launches Queqiao relay satellite to support Chang'e 4 lunar far side landing mission |work=GBTimes |first=Andrew |last=Jones |date=21 May 2018 |access-date=22 May 2018 |archive-date=22 May 2018 |archive-url=https://web.archive.org/web/20180522112109/https://gbtimes.com/china-launches-queqiao-relay-satellite-to-support-change-4-lunar-far-side-landing-mission |url-status=dead }} Queqiao is the first ever communication relay and radio astronomy satellite at operating its location.{{cite news |last1=Xu |first1=Luyuan |title=How China's lunar relay satellite arrived in its final orbit |url=http://www.planetary.org/blogs/guest-blogs/2018/20180615-queqiao-orbit-explainer.html |work=The Planetary Society |date=15 June 2018 |archive-url=https://web.archive.org/web/20181017123833/http://www.planetary.org/blogs/guest-blogs/2018/20180615-queqiao-orbit-explainer.html |archive-date=17 October 2018}}

|- style="background:#F2F2F2"

!scope=row| Spektr-RG

| Sun–Earth {{L2|nolink=yes}} || IKI RAN
DLR || Launched 13 July 2019. Roentgen and Gamma space observatory. Operational as of June 2020.{{cite web |url=https://www.esa.int/ESA_Multimedia/Images/2020/06/Illustration_of_the_Spektr-RG_spacecraft |title=Illustration of the Spektr-RG spacecraft |date=24 June 2020|access-date=25 December 2021}}

|- style="background:#F2F2F2"

!scope=row| Chang'e 5 Service Module

| Sun–Earth {{L1|nolink=yes}} || CNSA || Launched on 23 November 2020, arrived at L₁ halo orbit on 15 March 2021.

|- style="background:#F2F2F2"

!scope=row| James Webb Space Telescope (JWST)

| Sun–Earth {{L2|nolink=yes}} || NASA, ESA, CSA

| Launched on 25 December 2021, arrived at L₂ point on 24 January 2022. Operational as of 2022.{{Cite news|url=https://www.bbc.com/news/science-environment-59782057|title=James Webb Space Telescope lifts off on historic mission|work=BBC News |date=25 December 2021 |language=en|access-date=2021-12-25}}

|- style="background:#F2F2F2"

!scope=row| Euclid

| Sun–Earth {{L2|nolink=yes}} || ESA, NASA

| Launched on 1 July 2023, arrived at L₂ point on 28 July 2023. Currently in testing phase as of September 2023.{{cite web |url=https://www.esa.int/Science_Exploration/Space_Science/Euclid/Follow_Euclid_s_first_months_in_space#:~:text=In%20the%20month%20after%20its,arrived'%20at%20its%20destination%20orbit. |title=Follow Euclid's first months in space |date=25 August 2023 |access-date=2 September 2023 |work=ESA}}

|- style="background:#F2F2F2"

!scope=row| Aditya-L1

| Sun–Earth {{L1|nolink=yes}} || ISRO || Launched on 2 September 2023{{cite web |last=Graham |first=William |url=https://www.nasaspaceflight.com/2023/09/india-aditya-l1-pslv/ |title=India launches first solar research mission, Aditya-L1, aboard PSLV |date=2 September 2023 |access-date=2 September 2023 |work=NASASpaceFlight}} and was successfully inserted into an orbit about Sun-Earth L₁ point on 6 January 2024.{{Cite web |title=Halo-Orbit Insertion of Aditya-L1 Successfully Accomplished |url=https://www.isro.gov.in/halo-orbit-insertion-adtya-l1.html |access-date=2024-01-06 |website=www.isro.gov.in}}

|- style="background:#CCFFD9"

!scope=row| Chang'e 6 Service Module

| Sun–Earth {{L2|nolink=yes}} || CNSA || Launched on 3 May 2024, arrived at L₂ halo orbit on 9 September 2024.

|}

{{sticky header}}

• Trojan (celestial body)
• Co-orbital configuration

{{reflist}}

{{Planetary exploration}}

{{Space exploration lists and timelines}}

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{{DEFAULTSORT:Objects At Lagrangian Points}}

Category:Trojans (astronomy)

Category:Outer space lists

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