Function |
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Manufacturer | ArianeGroup |
Country of origin | European multi-national[a] |
Project cost | €3.6 billion[1] |
Cost per launch |
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Size | |
Height | 63 m (207 ft) |
Diameter | 5.4 m (18 ft) |
Mass |
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Stages | 2 |
Capacity | |
Payload to LEO | |
Mass |
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Payload to GTO | |
Orbital inclination | 6° |
Mass |
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Payload to GEO | |
Orbital inclination | 0° |
Mass | A64: 5,000 kg (11,000 lb)[3] |
Payload to SSO | |
Orbital inclination | 97.4° |
Mass |
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Payload to LTO | |
Orbital inclination | 97.4° |
Mass |
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Associated rockets | |
Family | Ariane |
Comparable | Falcon 9, Falcon Heavy, H3, Vulcan Centaur |
Launch history | |
Status | Active |
Launch sites | Guiana Space Centre, ELA-4 |
Total launches | 1 |
Partial failure(s) | 1 (VA262) |
First flight | 9 July 2024 (2024-07-09)[4] |
Boosters – P120C | |
No. boosters | 2 or 4 |
Diameter | 3 m (9.8 ft) |
Propellant mass | 142,000 kg (313,000 lb) |
Maximum thrust | 3,500 kN (790,000 lbf) each |
Total thrust |
|
Burn time | 130 seconds |
Propellant | HTPB / AP / Al |
First stage | |
Diameter | 5.4 m (18 ft) |
Propellant mass | 140,000 kg (310,000 lb) |
Powered by | 1 × Vulcain 2.1 |
Maximum thrust | 1,370 kN (310,000 lbf) |
Burn time | 468 seconds |
Propellant | LOX / LH2 |
Second stage | |
Diameter | 5.4 m (18 ft) |
Propellant mass | 31,000 kg (68,000 lb) |
Powered by | 1 × Vinci |
Maximum thrust | 180 kN (40,000 lbf) |
Burn time | Up to 900 seconds and four burns[5] |
Propellant | LOX / LH2 |
Ariane 6 is a European expendable launch system operated by Arianespace and developed and produced by ArianeGroup on behalf of the European Space Agency (ESA). It replaces Ariane 5, as part of the Ariane launch vehicle family.
This two-stage rocket utilizes liquid hydrogen and liquid oxygen (hydrolox) engines. The first stage features an upgraded Vulcain engine from Ariane 5, while the second uses the Vinci engine, designed specifically for this rocket. The Ariane 62 variant uses two P120 solid rocket boosters, while Ariane 64 uses four. The P120 booster is shared with Europe's other launch vehicle, Vega C, and is an improved version of the P80 rocket stage used on the original Vega.
Selected in December 2014 over an all-solid-fuel option, Ariane 6 was originally targeted for a 2020 launch. However, the program encountered delays, with the first launch occurring on 9 July 2024.
Ariane 6 was designed to halve launch costs and increase annual capacity from seven to eleven missions compared to its predecessor, but the program has faced controversy over high costs and lack of reusability versus competitors' rockets, such as SpaceX's Falcon 9.[needs update] European officials defend the program, saying it provides crucial independent space access for its member states.
Two variants of Ariane 6 are being developed:
The first (lower) stage of Ariane 6 is called the Lower Liquid Propulsion Module (LLPM). It is powered by a single Vulcain 2.1 engine, burning liquid hydrogen (LH2) with liquid oxygen (LOX).[8] Vulcain 2.1 is an updated version of the Vulcain 2 engine from Ariane 5 with lower manufacturing costs.[clarification needed] The LLPM is 5.4 m (18 ft) in diameter and contains approximately 140 tonnes (310,000 lb) of propellant.[9]
Additional thrust for the first stage will be provided by either two or four P120 model solid rocket boosters, known within Ariane 6 nomenclature as Equipped Solid Rockets (ESR).[8] Each booster contains approximately 142,000 kilograms (313,000 lb) of propellant and delivers up to 4,650 kN (1,050,000 lbf) of thrust. The P120 motor is also used in the first stage of the upgraded Vega C launcher. By sharing motors, production volumes can be increased, lowering production costs.[10] The first full-scale test of the ESR occurred at Kourou, French Guiana, on 16 July 2018, and the test completed successfully with thrust reaching 4,615 kN (1,037,000 lbf) in vacuum.[11][12][13]
The second (upper) stage of Ariane 6 is called the Upper Liquid Propulsion Module (ULPM). It shares the same 5.4 m (18 ft) diameter as the LLPM, and also burns liquid hydrogen with oxygen. It is powered by the Vinci engine, which delivers 180 kN (40,000 lbf) of thrust and is capable of multiple restarts.[8] The ULPM will carry about 31 tonnes (68,000 lb) of propellant.[10]
Ariane 6 was conceived in the early 2010s to be a replacement launch vehicle for Ariane 5, and a number of concepts and high-level designs were suggested and proposed during 2012–2015. Development funding from several European governments was secured by early 2016, and contracts were signed to begin detailed design and the build of test articles. In 2019, the maiden orbital flight had been planned for 2020,[14] however by May 2020, the planned initial launch date was delayed into 2021.[15] In October 2020, the European Space Agency (ESA) formally requested an additional €230 million in funding from the countries sponsoring the project to complete development of the rocket and get the vehicle to its first test flight, which had slipped to the second quarter of 2022.[16] By June 2021, the date had delayed to late 2022.[17] In June 2022, a delay was announced to "some time in 2023"[18] and by October 2022, ESA clarified that the first launch would be no earlier than the fourth quarter of 2023, while providing no public reason for the delay.[19] In August 2023, ESA announced that the date for the first launch had slipped again to 2024.[20]
Following detailed definition studies in 2012,[21] ESA announced in July 2013 the selection of the "PPH" (first stage of three P145 rocket motors, second stage of one P145 rocket motor, and H32 cryogenic upper stage) configuration for Ariane 6.[22] It would be capable of launching up to 6,500 kg (14,300 lb) to Geostationary transfer orbit (GTO),[23] with a first flight projected to be as early as 2021–2022.[24] Development was projected to cost €4 billion as of May 2013[update].[25] A 2014 study concluded that development cost could be reduced to about €3 billion by limiting contractors to five countries.[26]
While Ariane 5 typically launches one large and one medium satellite at a time, the PPH proposal for Ariane 6 was intended for single payloads, with an early 2014 price estimate of approximately US$95 million per launch.[27] The SpaceX Falcon 9 and the Chinese Long March 3B both launch smaller payloads but at lower prices, approximately $57 million and $72 million respectively as of early 2014, making the Falcon 9 launch of a midsize satellite competitive with the cost of the lower slot of a dual payload Ariane 5.[27] For lightweight all-electric satellites, Arianespace intended to use the restartable Vinci engine to deliver the satellites closer to their operational orbit than the Falcon 9 could, thus reducing the time required to transfer to geostationary orbit by several months.[27]
In June 2014, Airbus and Safran surprised ESA by announcing a counter proposal for the Ariane 6 project: a 50/50 joint venture to develop the rocket, which would also involve buying out the French government's CNES interest in Arianespace.[28][29]
This proposed launch system would come in two variants, Ariane 6.1 and Ariane 6.2.[30] While both would use a cryogenic main stage powered by a Vulcain 2 engine and two P145 solid boosters, Ariane 6.1 would feature a cryogenic upper stage powered by the Vinci engine and boost up to 8,500 kg (18,700 lb) to GTO, while Ariane 6.2 would use a lower-cost hypergolic upper stage powered by the Aestus engine. Ariane 6.1 would have the ability to launch two electrically powered satellites at once, while Ariane 6.2 would be focused on launching government payloads.
French newspaper La Tribune questioned whether Airbus Defence and Space could deliver on the promised costs for their Ariane 6 proposal, and whether Airbus and Safran Group could be trusted when they were found to be responsible for a failure of Ariane 5 flight 517 in 2002 and a more recent 2013 failure of the M51 ballistic missile.[31] The companies were also criticised for being unwilling to incur development risks, and asking for higher initial funding than originally planned – €2.6 billion instead of €2.3 billion. Estimated launch prices of €85 million for Ariane 6.1 and €69 million for Ariane 6.2 did not compare favorably to SpaceX offerings.[32] During the meeting of EU ministers in Geneva on 7 June 2014, these prices were deemed too high and no agreement with manufacturers was reached.[33]
Following criticism of the Ariane 6 PPH design, France unveiled a revised Ariane 6 proposal in September 2014.[34] This launcher would use a cryogenic main stage powered by the Vulcain 2 and upper stage powered by the Vinci, but vary the number of solid boosters. With two P120 boosters, Ariane 6 would launch up to 5,000 kg (11,000 lb) to GTO at a cost of €75 million. With four boosters, Ariane 6 would be able to launch two satellites totaling 11,000 kg (24,000 lb) to GTO at a cost of €90 million.[35]
This proposal, unlike Ariane 6 PPH, offered a scalable launcher while retaining Ariane 5's dual-launch capability. The proposal also included simplification of the industrial and institutional organisation along with a better and cheaper version of the Vulcain 2 engine for the main stage.[34][35] Although Ariane 6 was projected to have "lower estimated recurring production costs", it was projected to have "a higher overall development cost owing to the need for a new, Ariane 6-dedicated, launch pad".[36]
The Italian, French, and German space ministers met on 23 September 2014, in order to plan strategy and assess the possibility for agreement on funding for the Ariane 5 successor,[37] and in December 2014, ESA selected the Ariane 62 and Ariane 64 designs for development and funding.[38]
At the 2022 International Astronautical Congress, ArianeGroup announced the proposed "Smart Upper Stage for Innovative Exploration", a reusable upper stage for the 64 (or later) variant, capable of autonomous cargo operations or carrying five astronauts to LEO.[39]
In November 2015, an updated design of Ariane 64 and 62 was presented, with new nose cones on the boosters, main stage diameter increased to 5.4 m (18 ft), and the height decreased to 60 m (200 ft).[40]
The basic design for Ariane 6 was finalised in January 2016 as an expendable liquid-fuelled core stage plus expendable solid-rocket-boosters design. Development advanced into detailed design and production phases, with the first major contracts already signed.[41][42] Unlike previous Ariane rockets, which are assembled and fueled vertically before being transported to the launchpad, the Ariane 6 main stages were to be assembled horizontally at the new integration hall in Les Mureaux and then transported to French Guiana, to be erected and integrated with boosters and payload.[43]
The horizontal assembly process was inspired by the Russian tradition for Soyuz and Proton launchers – which had more recently been applied to the American Delta IV and Falcon 9 boosters[44] – with a stated goal of halving production costs.[45]
The industrial production process was completely overhauled, allowing synchronized workflow between several European production sites moving at a monthly cadence, which would enable twelve launches per year, doubling Ariane 5's yearly capacity.[43] To further lower the price, Ariane 6 engines were to use 3D printed components.[46] Ariane 6 was to be the first large rocket to use a laser ignition system developed by Austria's Carinthian Research Center (CTR), that was previously deployed in automotive and turbine engines.[47] A solid state laser offers an advantage over electrical ignition systems in that it is more flexible with regards to the location of the plasma within the combustion chamber, offers a much higher pulse power and can tolerate a wider range of fuel-air mixture ratios.[48]
Reorganisation of the industry behind a new launch vehicle, leading to the creation of Airbus Safran Launchers (ASL), also started a review by the French government into tax matters, and the European Commission over a possible conflict of interest if Airbus Defence and Space, a satellite manufacturer, were to purchase launches from ASL.[46]
While development was initially slated to be substantially complete in 2019, with an initial launch in 2020, the initial launch date has slipped several times: first to 2021,[49] then to 2022,[16][17] then to 2023,[18] and then to 2024.[50] In October 2022, Arianespace expected the maiden flight to occur in 2023,[19] although in December 2023, Arianespace once again set the flight to occur on 15 June 2024.[50] In June 2024, ESA Executive said its first launch was postponed to July 9th 2024.[51] The maiden flight took place 9 July 2024 and successfully orbited some satellites even though the mission did suffer some problems.
CNES began studies in 2010[52] on an alternative, reusable first stage for Ariane 6, using a mix of liquid oxygen and liquid methane rather than liquid hydrogen that is used in the 2016 Ariane 6 first-stage design. The methane-powered core could use one or more engines, matching capabilities of Ariane 64 with only two boosters instead of four. As of January 2015[update], the economic feasibility of reusing an entire stage remained in question. Concurrent with the liquid fly-back booster research in the late 1990s and early 2000s, CNES along with Russia concluded studies[when?] indicating that reusing the first stage was economically unviable as manufacturing ten rockets a year was cheaper and more feasible than recovery, refurbishment and loss of performance caused by reusability.[53] It was suggested[by whom?] that with a Arianespace launch schedule of 12 flights per year, an engine that could be reused a dozen times would produce a demand for only one engine per year, making supporting an ongoing engine manufacturing supply chain unviable.[citation needed]
In June 2015, Airbus Defence and Space announced that Adeline, a partially reusable first stage, would become operational between 2025 and 2030, and that it would be developed as a subsequent first stage for Ariane 6. Rather than developing a way to reuse an entire first stage (like SpaceX), Airbus proposed a system where only high-value parts would be safely returned using a winged module at the bottom of the rocket stack.[52]
In August 2016, ASL gave some more details about future development plans building on the Ariane 6 design. CEO Alain Charmeau revealed that Airbus Safran were now working along two main lines: first, continuing work (at the company's own expense) on the recoverable Adeline engine-and-avionics module; and second, beginning development of a next-generation engine to be called Prometheus. This engine would have about the same thrust as the Vulcain 2 currently powering Ariane 5, but would burn methane instead of liquid hydrogen. Charmeau was non-committal about whether Prometheus (still only in the first few months of development) could be used as an expendable replacement for the Vulcain 2 in Ariane 6, or whether it was tied to the re-usable Adeline design, saying only that "We are cautious, and we prefer to speak when are sure of what we announce... But certainly this engine could very well fit with the first stage of Ariane 6 one day", a decision on whether to proceed with Prometheus in an expendable or reusable role could be made between 2025 and 2030.[54]
In 2017, the Prometheus engine project was revealed to have the aim of reducing the engine unit cost from the €10 million of the Vulcain2 to €1 million and allowing the engine to be reused up to five times.[55] The engine development is said to be part of a broader effort – codename Ariane NEXT[56] – to reduce Ariane launch costs by a factor of two beyond improvements brought by Ariane 6. The Ariane NEXT initiative includes a reusable sounding rocket, Callisto, to test the performance of various fuels in new engine designs.[57]
In a January 2019 interview, Arianespace CEO Stéphane Israël said that the company would require four more institutional launches for Ariane 6 to sign a manufacturing contract. Launch contracts would be needed for the transitional period of 2020–2023 when Ariane 5 will be phased out and gradually replaced by Ariane 6. The company would require European institutions to become an anchor customer for the launcher. In response, ESA representatives said the agency was working on shifting the 2022 launch of the Jupiter Icy Moons Explorer from Ariane 5 ECA to Ariane 64, further indicating that there are other institutional customers in Europe that must put their weight behind the project, such as the European Organisation for the Exploitation of Meteorological Satellites (EUMETSAT) or the European Commission.
As of January 2019[update], Arianespace had sold three flights of the Ariane 6 launch vehicle.[58] One month later, they added a satellite internet constellation launch contract with OneWeb to utilize the maiden launch of Ariane 6 to help populate the large 600-satellite constellation.[59]
On 6 May 2019, Arianespace ordered the first production batch of 14 Ariane 6 rockets, for missions to be conducted between 2021 and 2023.[60]
Rocket components are transported by sea from Europe to the Guiana Space Centre aboard the Canopée, a cargo vessel that uses sails to assist with its propulsion, reducing fuel use.[61][62]
Ariane 6 is being developed in a public-private partnership with the majority of the funding coming from various ESA government sources — €2.815 billion — while €400 million is reported to be "industry's share".[63]
The ESA Council approved the project on 3 November 2016,[64] and the ESA Industrial Policy Committee released the required funds on 8 November 2016.[65]
In January 2020, two EU institutions, the European Investment Bank and the European Commission, loaned €100 million to Arianespace, drawing from the Horizon 2020 and Investment Plan for Europe corporate investment programmes. The 10-year loan's repayment is tied to the financial success of the Ariane 6 project.[66]
Flight No. | Date Time (UTC) |
Rocket type Serial No. |
Launch site | Payload | Payload mass | Orbit | Customers | Launch outcome |
---|---|---|---|---|---|---|---|---|
VA262 | 9 July 2024 19:00 |
Ariane 6 62 L6001[67] |
Guiana ELA-4 |
Multiple rideshare payloads | 1,600 kg[68] | LEO | Various | Partial failure |
Maiden flight of Ariane 6. It was a flight test carrying a mass simulator plus a number of small cubesats and other experiments as rideshare payloads. Rocket launched successfully to orbit and upper stage performed a second burn to release cubesats. During attempt to perform a third burn to deorbit the upper stage, the rocket's auxiliary propulsion system failed. This failure prevented the upper stage from relighting.[69][70][71][72] |
Date Time (UTC) |
Type | Payload | Orbit | Customers | Launch status | ||
---|---|---|---|---|---|---|---|
Q4 2024[71][70] | Ariane 62 | CSO-3 | SSO | CNES / DGA | Planned | ||
French military spy satellite. Despite the problem with the APU on Ariane 6's first flight, an Arianespace official said they are still "perfectly on track now to make the second launch this year".[71] | |||||||
2025[73][74] | Ariane 62 | Galileo FOC FM 29, 30 | MEO | ESA | Planned | ||
2025[73][74] | Ariane 62 | Galileo FOC FM 31, 32 | MEO | ESA | Planned | ||
2025[74] | Ariane 62 | Galileo FOC FM 33, 34 | MEO | ESA | Planned | ||
2025[75] | Ariane 64 | Intelsat-41, 44 | GTO | Intelsat | Planned | ||
2025[73][76] | Ariane 64 | Optus-11 | GTO | Optus | Planned | ||
2025[73][77][78] | Ariane 64 | Uhura-1 (Node-1)[79] | GTO | Skyloom | Planned | ||
2025[80] | Ariane 6 | Galileo G2 1 | MEO | ESA | Planned | ||
2025[81] | Ariane 6 | Hellas Sat 5 | GTO | Hellas Sat | Planned | ||
Q2 2026[82] | Ariane 64[83] | MTG-I2[84] | GTO | EUMETSAT | Planned | ||
H1 2026[85] | Ariane 64 | Intelsat 45 | GTO | Intelsat | Planned | ||
Q4 2026[86] | Ariane 64 | Multi-Launch Service (MLS) #1 rideshare mission | GTO | TBA | Planned | ||
2026[87] | Ariane 62[88] | PLATO | Sun–Earth L2 | ESA | Planned | ||
Q4 2027[86] | Ariane 64 | MLS #2 rideshare mission | GTO | TBA | Planned | ||
2027[89] | Ariane 64 | Earth Return Orbiter | Areocentric | ESA | Planned | ||
Q4 2028[86] | Ariane 64 | MLS #3 rideshare mission | GTO | TBA | Planned | ||
Q3 2029[86] | Ariane 64 | MLS #4 rideshare mission | GTO | TBA | Planned | ||
2029[90] | Ariane 62 | ARIEL, Comet Interceptor | Sun–Earth L2 | ESA | Planned | ||
2031[91] | Ariane 64 | Argonaut Mission 1 | TLI | ESA | Planned | ||
2035[92] | Ariane 64[93] | Athena | Sun–Earth L2, Halo orbit |
ESA | Planned | ||
2035[94] | Ariane 6 | LISA | Heliocentric | ESA | Planned | ||
TBD[95] | Ariane 64 | 18 launches of Project Kuiper (35–40 satellites)[96] | LEO | Kuiper Systems | Planned | ||
TBD[97] | Ariane 62 | Electra | GTO | SES S.A. / ESA | Planned | ||
TBD[97] | Ariane 62 | Eutelsat ×5 | GTO | Eutelsat | Planned |
Ariane 6 has been subject to criticism for its cost per launch and lack of reusability.
When initially approved by ESA in 2012, the rocket was envisioned as a modernized version of Ariane 5, optimized for cost. At the time, commercial competitors like SpaceX were already putting downward pressure on launch costs.[98][99] However, these companies had made few successful flights and had not yet proven that reusability would be economically beneficial, with the reusable Space Shuttle cited by some as an example to the contrary. In the more than a decade that Ariane 6 was in development, the project was delayed and went over budget. During that same time, SpaceX continued to iteratively develop its Falcon 9 rocket, nearly doubling its payload capacity and successfully landing rockets for reuse, making it more capable and far less costly than Ariane 6.[100][101][2]
European officials have defended Ariane 6 stating that its governments need access to space, independent from other states or private companies. They point to geopolitical events that cut off Europe's access to Russian Soyuz rockets in as an example of that need. They also defend the rocket's lack of reusability, arguing that it would not be economically viable given the rocket’s fewer planned launches.[102][103]
The ESA's member states agreed to subsidize the rocket with up to €340 million annually from its 16th to its 42nd flight (expected in 2031) in return for an 11% discount on launches.[102][104]
Ariane 6 would fly in 2020 assuming a development go-ahead in 2014. CNES's Ariane 6 team is operating under the "triple-seven" mantra, meaning seven years' development, 7 metric tons of satellite payload to geostationary transfer orbit and 70 million euros in launch costs. CNES estimates that Ariane 6 would cost 4 billion euros to develop, including ESA's customary program management fees and a 20% margin that ESA embeds in most of its programs.
As SpaceX and other launch contenders enter the sector – including new rockets in India, China and Russia – Europe is also investing in a midlife upgrade of Ariane 5, the Ariane 5 ME (Midterm Evolution), which aims to boost performance 20% with no corresponding increase in cost. At the same time, Europe is considering funding a smaller, less capable but more affordable successor to the heavy-lift launcher, Ariane 6, which would send up to 6,500 kg (14,300 lb) to GTO for around US$95 million per launch.
European space-hardware builders Airbus and Safran have proposed that the French and European space agencies scrap much of their previous 18 months' work on a next-generation Ariane 6 rocket in favour of a design that includes much more liquid propulsion.
The space ministers of France, Germany and Italy are scheduled to meet on September 23 in Zurich to assess how far they are from agreement on strategy and funding for Europe's next-generation Ariane rocket, upgrades to the light-lift Vega vehicle and — as a lower priority — their continued participation in the international space station. The meeting should give these governments a better sense of whether a formal conference of European Space Agency ministers scheduled for December 2 in Luxembourg will be able to make firm decisions, or will be limited to expressions of goodwill.
Officials said the preliminary plan calls for the Ariane 6 rocket to be integrated horizontally, a practice long used for Russian launchers and more recently adopted by United Launch Alliance's Delta 4 rocket family and SpaceX's Falcon 9 rocket.
When it comes to Ariane 64, we are at around US$90 to US$100 million, as opposed to Ariane 5, which is in terms of cost, around US$200 million. You see with the effort we're making, we want to reduce the cost around 40/50%, which is very ambitious.
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