Engineering:Long March (rocket family)

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Short description: Class of Chinese rockets


The Long March rockets are a family of expendable launch system rockets operated by the China Aerospace Science and Technology Corporation.[1] [2] The rockets are named after the Chinese Red Army's 1934–35 Long March military retreat during the Chinese Civil War.[3]

The Long March series has performed more than 500 launches, including missions to low Earth orbit, Sun-synchronous orbit, geostationary transfer orbit, and Earth-Moon transfer orbit. The new-generation carrier rockets, Long March 5, Long March 6, Long March 7, Long March 11, and Long March 8, have made their maiden flights. Among them, the Long March 5 has a low-Earth orbit carrying capacity of 25,000 kilograms, and a geosynchronous transfer orbit carrying capacity of 14,000 kilograms.[1][2]

History

China used the Long March 1 rocket to launch its first satellite, Dong Fang Hong 1 (lit. "The East is Red 1"), into low Earth orbit on 24 April 1970, becoming the fifth nation to achieve independent launch capability. Early launches had an inconsistent record, focusing on the launching of Chinese satellites. The Long March 1 was quickly replaced by the Long March 2 family of launchers.

Entry into commercial launch market

Long March 3A launch

After the U.S. Space Shuttle Challenger was destroyed in 1986, a growing commercial backlog gave China the chance to enter the international launch market. In September 1988, U.S. President Ronald Reagan agreed to allow U.S. satellites to be launched on Chinese rockets.[4] Reagan's satellite export policy would continue to 1998, through Bush and Clinton administrations, with 20 or more approvals.[5] AsiaSat 1, which had originally been launched by the Space Shuttle and retrieved by another Space Shuttle after a failure, was launched by a Long March 3 in 1990 as the first foreign payload on a Chinese rocket.

However, major setbacks occurred in 1992–1996. The Long March 2E was designed with a defective payload fairing, which collapsed when faced with the rocket's excessive vibration. After just seven launches, the Long March 2E destroyed the Optus B2 and Apstar 2 satellites and damaged AsiaSat 2.[6][7] The Long March 3B also experienced a catastrophic failure in 1996, veering off course shortly after liftoff and crashing into a nearby village. At least 6 people were killed on the ground, and the Intelsat 708 satellite was also destroyed.[8] A Long March 3 also experienced a partial failure in August 1996 during the launch of Chinasat-7.[9] Six Long March rockets (Chang Zheng 2C/SD) launched 12 Iridium satellites, about a sixth of Iridium satellites in the original fleet.[10]

United States embargo on Chinese launches

The involvement of United States companies in the Apstar 2 and Intelsat 708 investigations caused great controversy in the United States. In the Cox Report, the United States Congress accused Space Systems/Loral and Hughes Aircraft Company of transferring information that would improve the design of Chinese rockets and ballistic missiles.[11] Although the Long March was allowed to launch its commercial backlog, the United States Department of State has not approved any satellite export licenses to China since 1998. ChinaSat 8, which had been scheduled for launch in April 1999 on a Long March 3B rocket,[12] was placed in storage, sold to the Singapore company ProtoStar, and finally launched on a European rocket Ariane 5 in 2008.[11]

From 2005 to 2012, Long March rockets launched ITAR-free satellites made by the European company Thales Alenia Space.[13] However, Thales Alenia was forced to discontinue its ITAR-free satellite line in 2013 after the United States State Department fined a United States company for selling ITAR components.[14] Thales Alenia Space had long complained that "every satellite nut and bolt" was being ITAR-restricted, and the European Space Agency (ESA) accused the United States of using ITAR to block exports to China instead of protecting technology.[15] In 2016, an official at the United States Bureau of Industry and Security confirmed that "no U.S.-origin content, regardless of significance, regardless of whether it is incorporated into a foreign-made item, can go to China". The European aerospace industry is working on developing replacements for United States satellite components.[16]

Return to success

Long March 2F is the only human-rated launch vehicle of the Long March family.
Long March 2F is the only human-rated launch vehicle of the Long March family.

After the failures of 1992–1996, the troublesome Long March 2E was withdrawn from the market. Design changes were made to improve the reliability of Long March rockets. From October 1996 to April 2009, the Long March rocket family delivered 75 consecutive successful launches, including several major milestones in space flight:

  • On 15 October 2003, the Long March 2F rocket successfully launched the Shenzhou 5 spacecraft, carrying China's first astronaut into space. China became the third nation with independent human spaceflight capability, after the Soviet Union/Russia and the United States.
  • On 1 June 2007, Long March rockets completed their 100th launch overall.
  • On 24 October 2007, the Long March 3A successfully launched (10:05 UTC) the "Chang'e 1" lunar orbiting spacecraft from the Xichang Satellite Launch Center.

The Long March rockets have subsequently maintained an excellent reliability record. Since 2010, Long March launches have made up 15–25% of all space launches globally. Growing domestic demand has maintained a healthy manifest. International deals have been secured through a package deal that bundles the launch with a Chinese satellite, circumventing the United States embargo.[17]

Payloads

The Long March is China's primary expendable launch system family. The Shenzhou spacecraft and Chang'e lunar orbiters are also launched on the Long March rocket. The maximum payload for LEO is 25,000 kilograms (CZ-5B), the maximum payload for GTO is 14,000 kg (CZ-5). The next generation rocket Long March 5 variants will offer more payload in the future.

Propellants

Three engines using three different combination of propellants. From left to right: YF-20 using N2O4 and UDMH, YF-100 using LOX and kerosene, YF-77 using LOX and LH2

Long March 1's 1st and 2nd stage used nitric acid and unsymmetrical dimethylhydrazine (UDMH) propellants, and its upper stage used a spin-stabilized solid rocket engine.

Long March 2, Long March 3, Long March 4, the main stages and associated liquid rocket boosters use dinitrogen tetroxide (N2O4) as the oxidizing agent and UDMH as the fuel. The upper stages (third stage) of Long March 3 rockets use YF-73 and YF-75 engines, using liquid hydrogen (LH2) as the fuel and liquid oxygen (LOX) as the oxidizer.

The new generation of Long March rocket family, Long March 5 and its derivations Long March 6, Long March 7 and Long March 8 use non-toxic LOX/kerosene and LOX/LH2 liquid propellants (except in some upper stages where UDMH/N2O4 continues to be used).

Long March 11 is a solid-fuel rocket.

Variants

The Long March rockets are organized into several series:

The Long March 5, 6 and 7 are a newer generation of rockets sharing the new 1200 kN class YF-100 engines, which burns RP-1 / LOX, unlike earlier 2, 3 and 4 series which uses more expensive and dangerous N2O4 / UDMH propellants.[18] The 5 series is a heavy-lift launch vehicle, with a capacity of 25,000 kg to LEO while the 6 series is a small-lift launch vehicle with a capacity of 1,500 kg to LEO, and the 7 series is a medium-lift launch vehicle, with a capacity of 14,000 kg to LEO.

The 8 series is a new partially-renewable rocket with a capacity of 8,100 kg to LEO.

Comparison of Long March rockets
Model Status Stages Length
(m)
Max. diameter
(m)
Liftoff mass
(t)
Liftoff thrust
(kN)
Payload
(LEO, kg)
Payload (SSO, kg) Payload
(GTO, kg)
Long March 1 Retired 3 29.86 2.25 81.6 1020 300
Long March 1D Retired 3 28.22 2.25 81.1 1101.2 930
Long March 2A Retired 2 31.17 3.35 190 2,786 1,800
Long March 2C Active 2 43.72 3.35 245 2,961.6 4,000 2,100 1,250
Long March 2D Active 2 41.056
(without shield)
3.35 249.6 2,961.6 3,500 1,300
Long March 2E Retired [19] 2 (plus 4
Strap-on boosters)
49.686 3.35 464 5,923.2 9,500 4,350 3,500
Long March 2F Retired 2 (plus 4
Strap-on boosters)
58.34 3.35 493 6512 8,800
Long March 2F/G Active 2 (plus 4
Strap-on boosters)
58.34 3.35 493 6512 8,800
Long March 2F/T Active 2 (plus 4
Strap-on boosters)
58.34 3.35 493 6512 8,800
Long March 3 Retired [19] 3 44.9 3.35 205 2,961.6 5,000 1,600
Long March 3A Active 3 52.52 3.35 242 2,961.6 6,000 5,100 2,600
Long March 3B Retired [lower-alpha 1] 3 (plus 4
Strap-on boosters)
54.838 7.85 (including boosters) 425.8 5,923.2 11,200 6,850 5,100
Long March 3B/E Active 3 (plus 4
Strap-on boosters)
56.326 7.85 (including boosters) 458.97 5923.2 11,500 7,100 5,500
Long March 3C Retired 3 (plus 2
Strap-on boosters)
55.638 7.85 (including boosters) 345 4,442.4 9,100 6,450 3,900
Long March 3C/E Active 3 (plus 2
Strap-on boosters)
55.638 7.85 (including boosters) 345 4,442.4 9,100 6,450 3,900
Long March 4A Retired 3 41.9 3.35 241.1 2,961.6 3,800 1,600
Long March 4B Active 3 48 3.35 249.2 2,961.6 4,200 2,295
Long March 4C Active 3 48 3.35 249.2 2,961.6 4,200 2,947 1,500
Long March 5 [20][21] Active 2 (plus 4
Strap-on boosters
with optional
upper stage)
57 11.7 (including boosters) 854.5 10620 25,000 14,400
Long March 5B Active 1 (plus 4
Strap-on boosters)
53.7 11.7 (including boosters) 837.5 10620 25,000 15,000
Long March 6[22][23] Active 3 29 3.35 103 1200 1500 500
Long March 6A Active 2 (plus 4
Strap-on boosters)
50 7.35 (including boosters) 530 7230 ? 4,000
Long March 6C In development 2 ? ? ? ? 4,500 2,000 1,400
Long March 7 Active 2 (plus 4
Strap-on boosters)
53 7.85 (including boosters) 597 7,200 14,000 5,500
Long March 7A Active 3 (plus 4
Strap-on boosters)
60.13–60.7 7.85 (including boosters) 573 7,200 ? ? 7,800
Long March 8 Active 2 (plus 0–2
Strap-on boosters)
50.3 3.35–7.85 (including boosters) 356.6 4,800 8,100[24] 5,000[24] 2,800[24]
Long March 9 In development 3 114 10.6 4,369 60,000 150,000
Long March 10 In development 3 (plus 2 common core booster) 88.5–91.6 15 (including boosters) 2,187 26,250 70,000 32,000
Long March 11 Active 4 solid 20.8 ~2 58 1188 700 350
2A 2C 2D 2E 2F 3 3A 3B 3C 4A 4B 4C
CZ-2A.svg File:CZ-2C.svg Image:CZ-2D.svg File:CZ-2E.svg Image:CZ-2F.svg Image:CZ-3.svg Image:CZ-3A.svg File:CZ-3B.svg Image:CZ-3C.svg Image:CZ-4A.svg Image:CZ-4B.svg CZ-4C.svg

Long March 8

Main page: Engineering:Long March 8

The Long March 8 is a new series of launch vehicles, which is geared towards Sun-synchronous orbit (SSO) launches.[25] In early 2017, it was expected to be based on the Long March 7, and have two solid fuel boosters, and first launch by the end of 2018.[26] By 2019, it was intended to be partially reusable. The first stage will have legs and grid fins (like Falcon 9) and it may land with side boosters still attached.[27] The first Long March 8 was rolled out to for a test launch on or around 20 December 2020 and launched on 22 December 2020.[28] The second flight with no side boosters occurred on 27 February 2022, sending a national record of 22 satellites into SSO.[29]

Future development

Long March 9

Main page: Engineering:Long March 9

The Long March 9 (LM-9, CZ-9, or Changzheng 9, Chinese: 长征九号) is a Chinese super-heavy carrier rocket concept proposed in 2018 [30] that is currently in study. It is planned for a maximum payload capacity of 140,000 kg [31] to low Earth orbit (LEO), 50,000 kg to trans-lunar injection or 44,000 kg to Mars.[32][33] Its first flight is expected by 2028 or 2029 in preparation for a lunar landing sometime in the 2030s;[34] a sample return mission from Mars has been proposed as first major mission.[33] It has been stated that around 70% of the hardware and components needed for a test flight are currently undergoing testing, with the first engine test to occur by the end of 2018. The 2011 proposed design would be a three-staged rocket, with the initial core having a diameter of 10 meters and use a cluster of four engines. Multiple variants of the rocket have been proposed, CZ-9 being the largest with four liquid-fuel boosters with the aforementioned LEO payload capacity of 140,000 kg, CZ-9A having just two boosters and a LEO payload capacity of 100,000 kg, and finally CZ-9B having just the core stage and a LEO payload capacity of 50,000 kg.[35] Approved in 2021, the Long March 9 is classified as a super heavy-lift launch vehicle.[34] A very different design of LM-9 was announced in June 2021, with more engines and no external boosters.[36] Payload capacities are 160 tonnes to LEO and 53 tonnes to TLI.[37][38]

Long March 10

Main page: Engineering:Long March 10

The Long March 10, previously known as the "921 rocket", [39] is under development for crewed lunar missions. The nickname "921" refers to the founding date of China's human spaceflight program. Like the Long March 5, it uses 5-meter (16.4 ft) diameter rocket bodies and YF-100K engines, although with 7 engines on each of 3 cores.[40][41] The launch weight is 2187 tonnes, delivering 25 tonnes into trans-lunar injection.[42] The proposed crewed lunar mission uses two rockets; the crewed spacecraft and lunar landing stack launch separately and rendezvous in lunar orbit.[43] Development was announced at the 2020 China Space Conference.[42] As of 2022, the first flight of this triple-cored rocket is targeted for 2027.[44]

Origins

The Long March 1 rocket is derived from earlier Chinese 2-stage Intermediate-range ballistic missile (IRBM) DF-4, or Dong Feng 4 missile, and Long March 2, Long March 3, Long March 4 rocket families are derivatives of the Chinese 2-stage Intercontinental ballistic missile (ICBM) DF-5, or Dong Feng 5 missile. However, like its counterparts in both the United States and in Russia, the differing needs of space rockets and strategic missiles have caused the development of space rockets and missiles to diverge. The main goal of a launch vehicle is to maximize payload, while for strategic missiles increased throw weight is much less important than the ability to launch quickly and to survive a first strike. This divergence has become clear in the next generation of Long March rockets, which use cryogenic propellants in sharp contrast to the next generation of strategic missiles, which are mobile and solid fuelled.

The next generation of Long March rocket, Long March 5 rocket family, is a brand new design, while Long March 6 and Long March 7 can be seen as derivations because they use the liquid rocket booster design of Long March 5 to build small-to-mid capacity launch vehicles.

Launch sites

There are four launch centers in China. They are:

  • Jiuquan Satellite Launch Center
  • Taiyuan Satellite Launch Center
  • Wenchang Spacecraft Launch Site
  • Xichang Satellite Launch Center

Most of the commercial satellite launches of Long March vehicles have been from Xichang Satellite Launch Center, located in Xichang, Sichuan province. Wenchang Spacecraft Launch Site in Hainan province is under expansion and will be the main launch center for future commercial satellite launches. Long March launches also take place from the more military oriented Jiuquan Satellite Launch Center in Gansu province from which the crewed Shenzhou spacecraft also launches. Taiyuan Satellite Launch Center is located in Shanxi province and focuses on the launches of Sun-synchronous orbit (SSO) satellites.

On 5 June 2019, China launched a Long March 11 rocket from a mobile launch platform in the Yellow Sea.[45]

Commercial launch services

China markets launch services under the China Aerospace Science and Technology Corporation (China Great Wall Industry Corporation).[46] Its efforts to launch communications satellites were dealt a blow in the mid-1990s after the United States stopped issuing export licenses to companies to allow them to launch on Chinese launch vehicles out of fear that this would help China's military. In the face of this, Thales Alenia Space built the Chinasat-6B satellite with no components from the United States whatsoever. This allowed it to be launched on a Chinese launch vehicle without violating United States International Traffic in Arms Regulations (ITAR) restrictions.[47] The launch, on a Long March 3B rocket, was successfully conducted on 5 July 2007.

A Chinese Long March 2D launched VRSS-1 (Venezuelan Remote Sensing Satellite-1) of Venezuela, "Francisco de Miranda" on 29 September 2012.

Notes

  1. CZ-3B last flown in September 2012 on flight 22 of the combined CZ-3B and CZ-3B/E launch list; subsequent 43 flights in said list (to February 2020) have all been of the CZ-3B/E variant.

See also

References

  1. 1.0 1.1 "长征_中国航天科技集团有限公司". http://www.spacechina.com/n25/n142/n353157/n353161/index.html. 
  2. 2.0 2.1 "Launch Vehicles". May 28, 2022. http://english.spacechina.com/n16421/n17215/n17269/c2427295/content.html. 
  3. "我国运载火箭为什么以"长征"命名-新华网". http://www.xinhuanet.com//politics/2016-10/12/c_1119701405.htm. 
  4. Stevenson, Richard W. (September 16, 1988). "Shaky Start for Rocket Business". The New York Times. https://www.nytimes.com/1988/09/16/business/shaky-start-for-rocket-business.html. 
  5. "Clinton Defends China Satellite Waiver – May 22, 1998". https://www.cnn.com/ALLPOLITICS/1998/05/22/china.money/. 
  6. Zinger, Kurtis J. (2014). An Overreaction that Destroyed an Industry: The Past, Present, and Future of U.S. Satellite Export Controls (Report). http://lawreview.colorado.edu/wp-content/uploads/2015/07/13.-86.1-Zinger_Final.pdf. Retrieved November 28, 2017. 
  7. "CZ-2E Space Launch Vehicle". https://www.globalsecurity.org/space/world/china/cz-2e.htm. 
  8. Lan, Chen. "Mist around the CZ-3B disaster, part 1". The Space Review. http://www.thespacereview.com/article/2323/1. 
  9. "NASA – NSSDCA – Spacecraft – Details". https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1996-048A. 
  10. Graham, William (2018-03-30). "Iridium NEXT-5 satellites ride to orbit on SpaceX Falcon 9" (in en-US). https://www.nasaspaceflight.com/2018/03/iridium-next-5-satellites-spacex-falcon-9/. 
  11. 11.0 11.1 Zelnio, Ryan (January 9, 2006). "A short history of export control policy". The Space Review. http://www.thespacereview.com/article/528/1. 
  12. Associate Administrator for Commercial Space Transportation, Federal Aviation Administration (1999). Commercial Space Transportation Quarterly Launch Report (Report). https://www.faa.gov/about/office_org/headquarters_offices/ast/media/quarter9902.pdf. Retrieved November 28, 2017.  This article incorporates text from this source, which is in the public domain.
  13. Harvey, Brian (2013). China in Space: The Great Leap Forward. New York: Springer. pp. 160–162. ISBN 9781461450436. https://archive.org/details/chinaspacegreatl00harv. 
  14. Ferster, Warren (5 September 2013). "U.S. Satellite Component Maker Fined US$8 Million for ITAR Violations". SpaceNews. http://spacenews.com/37071us-satellite-component-maker-fined-8-million-for-itar-violations/. 
  15. de Selding, Peter B. (9 August 2013). "Thales Alenia Space: U.S. Suppliers at Fault in "ITAR-free" Misnomer". SpaceNews. http://spacenews.com/36706thales-alenia-space-us-suppliers-at-fault-in-itar-free-misnomer/. 
  16. de Selding, Peter B. (April 14, 2016). "U.S. ITAR satellite export regime's effects still strong in Europe". SpaceNews. http://spacenews.com/u-s-itar-satellite-export-regimes-effects-still-strong-in-europe/. 
  17. Henry, Caleb (August 22, 2017). "Back-to-back commercial satellite wins leave China Great Wall hungry for more". SpaceNews. http://spacenews.com/back-to-back-commercial-satellite-wins-leave-china-great-wall-hungry-for-more/. 
  18. SINA News Sina, 19 November 2010, [1]
  19. 19.0 19.1 "CZ". Astronautix.com. http://www.astronautix.com/lvs/cz.htm. 
  20. "cz5". SinoDefence. http://www.sinodefence.com/strategic/launchvehicle/cz5.asp. 
  21. "CZ-NGLV". astronautix.com. http://www.astronautix.com/lvs/cznglv.htm. 
  22. "China starts developing Long March 6 carrier rockets for space mission". Xinhuanet News. September 6, 2009. http://news.xinhuanet.com/english/2009-09/06/content_12003432.htm. 
  23. "ChangZheng 6 (Long March 6) Launch Vehicle". SinoDefence.com. February 20, 2009. http://www.sinodefence.com/space/launcher/changzheng6.asp. 
  24. 24.0 24.1 24.2 Rui C. Barbosa (December 22, 2020). "Long March 8 – a future reusable rocket – conducts debut launch". https://www.nasaspaceflight.com/2020/12/long-march-8-debuts-nine-satellites/. 
  25. "中国长征系列运载火箭大家族将添六大新成员-中新网". http://www.chinanews.com/mil/2015/03-07/7109962.shtml. 
  26. Jones (February 2017). "hina is aiming to launch a new Long March 8 rocket". https://gbtimes.com/china-launch-new-long-march-8-rocket-end-2018. 
  27. Meet the Long March 8 - January 2020 Includes CGI image of first stage landing
  28. Jones, Andrew (December 18, 2020). "China rolls out Long March 8 rocket for weekend test flight". SpaceNews. https://spacenews.com/china-rolls-out-long-march-8-rocket-for-weekend-test-flight/. 
  29. Jones, Andrew (27 February 2022). "China launches national record 22 satellites on Long March 8 commercial rideshare". SpaceNews. https://spacenews.com/china-launches-national-record-22-satellites-on-long-march-8-commercial-rideshare/. 
  30. Jones, Andrew (5 July 2018). "China reveals details for super-heavy-lift Long March 9 and reusable Long March 8 rockets". SpaceNews. https://spacenews.com/china-reveals-details-for-super-heavy-lift-long-march-9-and-reusable-long-march-8-rockets/. 
  31. "First Look: China's Big New Rockets". AmericaSpace. July 18, 2012. http://www.americaspace.com/?p=22881. 
  32. "梁小虹委员:我国重型运载火箭正着手立项 与美俄同步". http://scitech.people.com.cn/GB/14054670.html. 
  33. 33.0 33.1 "China reveals details for super-heavy-lift Long March 9 and reusable Long March 8 rockets". 5 July 2018. https://timesofindia.indiatimes.com//world/china/china-aims-to-outstrip-nasa-with-super-powerful-rocket/articleshow/64829693.cms?. 
  34. 34.0 34.1 Berger, Eric (24 February 2021). "China officially plans to move ahead with super-heavy Long March 9 rocket". Ars Technica. https://arstechnica.com/science/2021/02/china-officially-plans-to-move-ahead-with-super-heavy-long-march-9-rocket/. 
  35. "China Aims for Humanity's Return to the Moon in the 2030s". 2016-05-05. https://www.popsci.com/china-aims-for-humanitys-return-to-moon-in-2030s. 
  36. Red Heaven: China sets its sights on the stars (part 1)
  37. "China National Space Day". 2022-04-25. https://kevinjamesng.com/2022/04/25/cnsa-chinanationalspaceadministration-%E5%9B%BD%E5%AE%B6%E8%88%AA%E5%A4%A9%E5%B1%80-beltandroadinitiative-apirl2022%E4%B8%AD%E5%9B%BD%E5%A4%A9%E6%96%87%E6%97%A5-chinaspaceday-%E9%95%BF/. 
  38. "10 more engines!The Long March 9 rocket has a new configuration, which is thicker and taller and can be reused". 2022-04-27. https://inf.news/en/military/5249f3bc1a4f016c8781df63714ee5e3.html. 
  39. 汪淼 (2023-02-24). "我国新一代载人运载火箭命名为"长征十号",将用于登月任务" (in zh-hans). IT之家. https://m.ithome.com/html/675669.htm. Retrieved 2023-02-25. 
  40. Lund, J. (October 7, 2020). "China's Mysterious Manned Moon Rocket". https://j-lund.medium.com/chinas-mysterious-manned-moon-rocket-5d37068c2480. 
  41. Jones, Andrew (17 December 2021). "China's new rocket for crewed moon missions to launch around 2026". SpaceNews. https://spacenews.com/chinas-new-rocket-for-crewed-moon-missions-to-launch-around-2026/. 
  42. 42.0 42.1 Jones, Andrew (October 1, 2020). "China is building a new rocket to fly its astronauts on the Moon". SPACE.com. https://www.space.com/china-rocket-for-crewed-moon-missions. 
  43. Jones, Andrew (October 30, 2020). "China outlines architecture for future crewed moon landings". SpaceNews. https://spacenews.com/china-outlines-architecture-for-future-crewed-moon-landings/. 
  44. Jones, Andrew (11 November 2022). "China's huge new crew-launching moon rocket could fly for 1st time in 2027". Space.com. https://www.space.com/china-crew-launching-moon-rocket-2027-debut. 
  45. "China Gains New Flexible Launch Capabilities with First Sea Launch". 6 June 2019. https://www.space.com/china-gains-flexible-capabilities-sea-launch.html. 
  46. "About CGWIC". CGWIC. http://www.cgwic.com/about/index.html. 
  47. "China launches satellite despite restrictions". USA Today. July 6, 2007. https://www.usatoday.com/tech/science/space/2007-07-06-china-launches-satellite_N.htm. 

External links