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Space Launch System

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This article is about the NASA rocket family. For the similarly-named US Air Force project of the 1960s, see Space Launcher System.
Space Launch System
Artist's rendering of the SLS Block 1 launching with Orion.
FunctionLaunch vehicle
ManufacturerBoeing, United Launch Alliance, Orbital ATK, Aerojet Rocketdyne
Country of originUnited States
Project costUS$7 billion (2014-18, 2014 estimate),[1] to
$35 billion (until 2025, 2011 est.)[2][3][better source needed]
Cost per launchUS$500 million (2012 projection)[4]
Size
Diameter27 ft 7 in (8.4 m) (core stage)
Stages2
Capacity
Payload to LEO
Mass150,000 to 290,000 lb (70,000 to 130,000 kg)
Associated rockets
FamilyShuttle-Derived Launch Vehicles
ComparableSaturn V, Energia, N-1
Launch history
StatusUndergoing development
Launch sitesLC-39B, Kennedy Space Center
First flightNo later than November 2018[5]
Type of passengers/cargoOrion MPCV, Europa Multiple-Flyby Mission, Uranus orbiter and probe
Boosters (Block 1)
No. boosters2 five-segment Solid Rocket Boosters
Powered byoff
Maximum thrust3,600,000 lbf (16,000 kN)
Total thrust7,200,000 lbf (32,000 kN)
Specific impulse269 seconds (2.64 km/s) (vacuum)
Burn time124 seconds
PropellantPBAN, APCP
First stage (Block 1, 1B, 2) – Core Stage
Diameter27 ft 7 in (8.4 m)
Empty mass187,990 lb (85,270 kg)
Gross mass2,159,322 lb (979,452 kg)
Powered by4 RS-25D/E[6]
Maximum thrust1,670,000 lbf (7,440 kN)
Specific impulse363 seconds (3.56 km/s) (sea level), 452 seconds (4.43 km/s) (vacuum)
PropellantLH2/LOX
Second stage (Block 1) – ICPS
Height44 ft 11 in (13.7 m)
Diameter16 ft 5 in (5 m)
Empty mass7,690 lb (3,490 kg)
Gross mass67,700 lb (30,710 kg)
Powered by1 RL10B-2
Maximum thrust24,800 lbf (110.1 kN)
Specific impulse462 seconds (4.53 km/s)
Burn time1125 seconds
PropellantLH2/LOX
Second stage (Block 1B, Block 2) – Exploration Upper Stage
Diameter27 ft 7 in (8.4 m)
Powered by4 RL10
Maximum thrust99,000 lbf (440 kN)
PropellantLH2/LOX
[edit on Wikidata]

The Space Launch System (SLS) is an American Space Shuttle-derived heavy expendable launch vehicle being designed by NASA. It follows the cancellation of the Constellation program, and is to replace the retired Space Shuttle. The NASA Authorization Act of 2010 envisions the transformation of the Constellation program's Ares I and Ares V vehicle designs into a single launch vehicle usable for both crew and cargo, similar to the Ares IV. SLS will be the world's most powerful rocket with about 20% more thrust than Saturn V and a comparable payload capacity.[7][8][9]

The SLS launch vehicle is to be upgraded over time with more powerful versions. Its initial Block 1 version is to lift a payload of 70 metric tons to low Earth orbit (LEO), which will be increased with the debut of Block 1B and the Exploration Upper Stage.[10] Block 2 will replace the initial Shuttle-derived boosters with advanced boosters and is planned to have a LEO capability of more than 130 metric tons to meet the congressional requirement.[11] These upgrades will allow the SLS to lift astronauts and hardware to various beyond-LEO destinations: on a circumlunar trajectory as part of Exploration Mission 1 with Block 1, to a near-Earth asteroid in Exploration Mission 2 with Block 1B, and to Mars with Block 2. The SLS will launch the Orion Crew and Service Module and may support trips to the International Space Station if necessary. SLS will use the ground operations and launch facilities at NASA's Kennedy Space Center, Florida.

During the joint Senate-NASA presentation in September 2011, it was stated that the SLS program has a projected development cost of $18 billion through 2017, with $10 billion for the SLS rocket, $6 billion for the Orion Multi-Purpose Crew Vehicle and $2 billion for upgrades to the launch pad and other facilities at Kennedy Space Center.[12][13]

Design and development

Space Launch System's planned upgrade path

On September 14, 2011, NASA announced its design selection for the new launch system, declaring that it, in combination with the Orion spacecraft,[14] would take the agency's astronauts farther into space than ever before and provide the cornerstone for future US human space exploration efforts.[15][16][17]

Three versions of the SLS launch vehicle are planned: Block 1, Block 1B, and Block 2. Each will use the same core stage with four main engines, but Block 1B will feature a more powerful second stage called the Exploration Upper Stage (EUS), and Block 2 will combine the EUS with upgraded boosters. Block 1 has a baseline LEO payload capacity of 70 metric tons (77 short tons) and Block 1B has a baseline of 105 metric tons (116 short tons). The proposed Block 2 will have lift capacity of 130 metric tons (140 short tons), which is similar to that of the Saturn V.[11][18] Some sources state this would make the SLS the most capable heavy lift vehicle built;[19][20] although the Saturn V lifted approximately 140 metric tons to LEO in the Apollo 17 mission.[7][21]

During the development of the SLS a number of configurations were considered, including a Block 0 with three main engines,[22] a Block 1A variant that would have upgraded the vehicle's boosters instead of its second stage,[22] and a Block 2 with five main engines and a different second stage, the Earth Departure Stage, with up to three J-2X engines.[23] In February 2015, it was reported that NASA evaluations showed "over performance" versus the baseline payload for Block 1 and Block 1B configurations.[24]

On July 31, 2013 the SLS passed the Preliminary Design Review (PDR). The review encompassed all aspects of the SLS' design, not only the rocket and boosters but also ground support and logistical arrangements.[25] On August 7, 2014 the SLS Block 1 passed a milestone known as Key Decision Point C and entered full-scale development, with an estimated launch date of November 2018.[26][5]

Vehicle description

Rendering of the SLS Block 1 with its older black-and-white paint scheme, showing the large core stage, two 5-segment SRBs, and the smaller upper stage.

Core stage

The core stage will be 8.4 meters (28 ft) in diameter and utilize four RS-25 engines.[6][22] Initial flights will use modified RS-25D engines left over from the Space Shuttle program;[27] later flights are expected to switch to a cheaper version of the engine not intended for reuse.[28] The stage's structure will consist of a modified Space Shuttle External Tank with the aft section adapted to accept the rocket's Main Propulsion System (MPS) and the top converted to host an interstage structure.[19][29] It will be fabricated at the Michoud Assembly Facility.[30]

The core stage will be common across all currently planned evolutions of the SLS. Initial planning included studies of a smaller Block 0 configuration with three RS-25 engines,[31][32] which was eliminated to avoid the need to substantially redesign the core stage for more powerful variants.[22] Likewise, while early Block 2 plans included five RS-25 engines on the core,[23] it was later baselined with four engines.[24]

Boosters

Artist's rendering of a Block 1 SLS
Comparison of the Saturn V, Space Shuttle, Ares I, Ares V, Ares IV, SLS Block I and SLS Block II

Shuttle-derived solid rocket boosters

Blocks 1 and 1B of the SLS will use two five-segment Solid Rocket Boosters (SRBs), which are based on the four-segment Space Shuttle Solid Rocket Boosters. Modifications for the SLS included the addition of a center booster segment, new avionics, and new insulation which eliminates the Shuttle SRB's asbestos and is 860 kg (1,900 lb) lighter. The five-segment SRBs provide approximately 25% more total impulse than the Shuttle SRB and will not be recovered after use.[33][34]

Orbital ATK (formerly Alliant Techsystems) has completed four full-scale, full-duration static fire tests of the five-segment SRB. Development Motor 1 (DM-1) was tested on September 10, 2009; DM-2 was tested on August 31, 2010, and DM-3 on September 8, 2011. The DM-2 motor was cooled to a core temperature of 40 °F (4 °C), and DM-3 was heated to above 90 °F (32 °C). These tests validated motor performance at extreme temperatures.[35][36][37] Qualification Motor 1 (QM-1) was tested on March 10, 2015.[38]

Advanced boosters

For Block 2, NASA plans to switch from Shuttle-derived five-segment SRBs to advanced boosters.[39] This will occur after development of the Exploration Upper Stage for Block 1B. Early plans would have developed advanced boosters before an updated second stage; this configuration was called Block 1A. By 2012 NASA planned to select these new boosters through an Advanced Booster Competition which was to be held in 2015.[6][40] Several companies proposed boosters for this competition:

  • Aerojet, in partnership with Teledyne Brown, offered a booster powered by three AJ1E6 engines, which would be a newly developed LOX/RP-1 oxidizer-rich staged combustion engine. Each AJ1E6 engine would produce 4,900 kN (1,100,000 lbf) thrust using a single turbopump to supply dual combustion chambers.[41] On February 14, 2013, NASA awarded Aerojet a $23.3 million, 30-month contract to build a 2,400 kN (550,000 lbf) main injector and thrust chamber.[42]
  • ATK proposed an advanced SRB nicknamed "Dark Knight". This booster would switch from a steel case to one made of lighter composite material, use a more energetic propellant, and reduce the number of segments from five to four.[43] It would deliver over 20,000 kN (4,500,000 lbf) maximum thrust and weigh 790,000 kg (1,750,000 lb) at ignition. According to ATK, the advanced booster would be 40% less expensive than the Shuttle-derived five-segment SRB. It is uncertain if the booster will allow SLS to deliver the mandated 130 t to LEO without the addition of a fifth engine to the core stage,[24] as a 2013 analysis indicated a maximum capacity of 113 t with the baselined four-engine core.[44]
  • Pratt & Whitney Rocketdyne and Dynetics proposed a liquid-fueled booster named "Pyrios".[45] The booster would use two F-1B engines which together would deliver a maximum thrust of 16,000 kN (3,600,000 lbf) total, and be able to continuously throttle down to a minimum of 12,000 kN (2,600,000 lbf). The F-1B would be derived from the F-1 engine, which powered the first stage of the Saturn V. It would have been easier to assemble, with fewer parts and a simplified design,[46] while providing improved efficiency and a thrust increase of 110 kN (25,000 lbf).[47] Estimates in 2012 indicated that the Pyrios booster could increase Block 2 low-Earth orbit payload to 150 t, 20 t more than the baseline.[48]

Christopher Crumbly, manager of NASA’s SLS advanced development office in January 2013 commented on the booster competition, "The F-1 has great advantages because it is a gas generator and has a very simple cycle. The oxygen-rich staged combustion cycle [Aerojet’s engine] has great advantages because it has a higher specific impulse. The Russians have been flying ox[ygen]-rich for a long time. Either one can work. The solids [of ATK] can work."[49]

Later analysis showed the Block 1A configuration would result in high acceleration which would be unsuitable for Orion and could require a costly redesign of the Block 1 core.[50] In 2014, NASA confirmed the development of Block 1B instead of Block 1A and called off the 2015 booster competition.[24][51] In February 2015, it was reported that SLS is expected to fly with the five-segment SRB until at least the late 2020s, and modifications to Launch Pad 39B, its flame trench, and SLS's Mobile Launcher Platform were evaluated based on SLS launching with solid-fuel boosters.[24]

Upper stage

An RL10 engine, like the one pictured above, will be used as the second stage engine in both the ICPS and EUS upper stages.

Interim Cryogenic Propulsion Stage

Block 1, scheduled to fly Exploration Mission 1 (EM-1) by November 2018,[5] will use the Interim Cryogenic Propulsion Stage (ICPS). This stage will be a modified Delta IV 5-meter Delta Cryogenic Second Stage (DCSS),[52] and will be powered by a single RL10B-2. Block 1 will be capable of lifting 70 t in this configuration, however the ICPS will be considered part of the payload and be placed into an initial 1,800 km by -93 km suborbital trajectory to ensure safe disposal of the core stage. ICPS will perform an orbital insertion burn at apogee, and then a translunar injection burn to send the uncrewed Orion on a circumlunar excursion.[53]

Exploration Upper Stage

The Exploration Upper Stage (EUS) is scheduled to debut on Exploration Mission 2 (EM-2). It is expected to be used by Block 1B and Block 2 and, like the core stage, will be 8.4 meters in diameter. The EUS would be powered by four RL10 engines,[54] and would complete the SLS ascent phase and then re-ignite to send its payload to destinations beyond low-Earth orbit, similar to the role performed by the Saturn V's 3rd stage, the J-2 powered S-IVB.[55]

Other upper stages

The Bimodal Nuclear Thermal Rocket engines on the Mars Transfer Vehicle (MTV). Cold launched, it would be assembled in-orbit by a number of Block 2 SLS payload lifts. The Orion crew capsule is docked on the right.
  • The Earth Departure Stage, powered by J-2X engines,[56][57] was to be the upper stage of the Block 2 SLS had NASA decided to develop Block 1A instead of Block 1B and the EUS.[55]
  • An additional beyond-LEO engine for interplanetary travel from Earth orbit to Mars orbit, and back, is being studied as of 2013 at Marshall Space Flight Center with a focus on nuclear thermal rocket (NTR) engines.[58] In historical ground testing, NTRs proved to be at least twice as efficient as the most advanced chemical engines, allowing quicker transfer time and increased cargo capacity. The shorter flight duration, estimated at 3–4 months with NTR engines,[59] compared to 8–9 months using chemical engines,[60] would reduce crew exposure to potentially harmful and difficult to shield cosmic rays.[61][62][63][64] NTR engines, such as the Pewee of Project Rover, were selected in the Mars Design Reference Architecture (DRA).[62][65][66][67]
  • In 2013, NASA and Boeing analyzed the performance of several second stage options. The analysis was based on a second stage usable propellant load of 105 metric tons, except for the Block 1 and ICPS, which will carry 27.1 metric tons. The ICPS upper stage and upper stages using four RL10 engines and two MB60 engines and one J-2X engine were studied.[68] In 2014, NASA also considered using the European Vinci instead of the RL10. The Vinci offers the same specific impulse but with 64% greater thrust, which would allow for a reduction of one or two of the four second stage engines for the same performance for a lower cost.[69][70]

Robotic exploration missions to Jupiter's water-ice moon Europa are increasingly seen as well suited to the lift capabilities of the Block 1B SLS.[71]

Fabrication and testing

In mid-November 2014, construction of the first SLS began using the new welding system at NASA's Michoud Assembly Facility, where major rocket parts will be assembled.[72]

The SLS will have the ability to tolerate a minimum of 13 tanking cycles due to launch scrubs and other launch delays before launch. The assembled rocket is to be able to remain at the launch pad for a minimum of 180 days and can remain in stacked configuration for at least 200 days without destacking.[73]

In January 2015, NASA began test firing RS-25 engines in preparation for use on SLS. Tests continued throughout Spring of 2015. A second round of similar tests are planned for 2016.[28]

Multiple facilities throughout the country have started full scale fabrication of different segments of the launch vehicle. Orbital ATK began casting propellant for the solid rocket boosters and manufacturing parts for the boosters in 2016. The company test fired a solid rocket booster in early 2015, and a second booster firing is planned for early 2016. Confidence article builds for the core stage began on 5 January 2016 and were expected to be completed in late January of that year. Once completed the test articles will be sent to ensure structural integrity at Marshall Spaceflight Center. The ICPS for EM-1 was slated for assembly in late January, and a structural test article was delivered to NASA in 2015 for confidence testing.[74]

Program costs and funding

In August 2014, as the SLS program passed its Key Decision Point C review and entered full development, costs from February 2014 until its planned launch in September 2018 were estimated at $7.021 billion.[26] Ground systems modifications and construction would require an additional $1.8 billion over the same time period. As of February 2015 the Orion spacecraft was expected to enter its Key Decision Point C review in the first half of 2015.[75]

During the joint Senate-NASA presentation in September 2011, it was stated that the SLS program had a projected development cost of $18 billion through 2017, with $10 billion for the SLS rocket, $6 billion for the Orion Multi-Purpose Crew Vehicle and $2 billion for upgrades to the launch pad and other facilities at Kennedy Space Center.[12] These costs and schedule were considered optimistic in an independent 2011 cost assessment report by Booz Allen Hamilton for NASA.[76] An unofficial 2011 NASA document estimated the cost of the program through 2025 to total at least $41bn for four 70 t launches (1 unmanned, 3 manned),[2][3] with the 130 t version ready no earlier than 2030.[77]

The Human Exploration Framework Team (HEFT) estimated unit costs for Block 0 at $1.6bn and Block 1 at $1.86bn in 2010.[78] However, since these estimates were made the Block 0 SLS vehicle was dropped in late 2011, and the design was not completed.[79] The Space Review estimated the cost per launch at $5 billion, depending on the rate of launches.[80][81] NASA announced in 2013 that the European Space Agency will build the Orion Service Module.[82]

NASA SLS deputy project manager Jody Singer at Marshall Space Flight Center, Huntsville, Alabama stated in September 2012 that $500 million per launch is a reasonable target cost for SLS, with a relatively minor dependence of costs on launch capability.[4] By comparison, the cost for a Saturn V launch was US$185 to US$189 million in 1969-1971 dollars,[83][84] which is roughly US$1.2 billion in 2014 dollars.[85]

On July 24, 2014, Government Accountability Office audit predicted that SLS will not launch by the end of 2017 as originally planned since NASA is not receiving sufficient funding.[86]

For Fiscal Year 2015, NASA received an appropriation of US$1.7 billion from Congress for SLS, an amount that was approximately US$320 million greater than the amount requested by the Obama administration.[87]

Criticism

The Space Access Society, Space Frontier Foundation and The Planetary Society called for cancellation of the project, arguing that SLS will consume the funds for other projects from the NASA budget and will not reduce launch costs.[88][89][90] U.S. Representative Dana Rohrabacher and others added that instead, a propellant depot should be developed and the Commercial Crew Development program accelerated.[88][91][92][93][94] Two studies, one not publicly released from NASA[95][96] and another from the Georgia Institute of Technology, show this option to be a possibly cheaper alternative.[97][98]

Others suggest it will cost less to use an existing lower payload capacity rocket (Atlas V, Delta IV, Falcon 9, or the derivative Falcon Heavy), with on-orbit assembly and propellant depots as needed, rather than develop a new launch vehicle for space exploration without competition for the whole design.[99][100][101][102][103] The Augustine commission proposed an option for a commercial 75 metric ton launcher with lower operating costs, and noted that a 40 to 60 t launcher can support lunar exploration.[104]

Mars Society founder Robert Zubrin, who co-authored the Mars Direct concept, suggested that a heavy lift vehicle should be developed for $5 billion on fixed-price requests for proposal. Zubrin also disagrees with those that say the U.S. does not need a heavy-lift vehicle.[105] Based upon extrapolations of increased payload lift capabilities from past experience[citation needed] with SpaceX's Falcon launch vehicles, SpaceX CEO Elon Musk stated in 2010 that he would "personally guarantee" that his company could build the conceptual Falcon XX, a vehicle in the 140-150 t payload range, for $2.5 billion, or $300 million per launch, but cautioned that this price tag did not include a potential upper-stage upgrade.[106][107] SpaceX's privately-funded MCT launch vehicle, powered by multiple Raptor engines, has also been proposed for lifting very large payloads from Earth in the 2020s.[108]

Rep. Tom McClintock and other groups argue that the Congressional mandates forcing NASA to use Space Shuttle components for SLS amounts to a de facto non-competitive, single source requirement assuring contracts to existing shuttle suppliers, and calling the Government Accountability Office (GAO) to investigate possible violations of the Competition in Contracting Act (CICA).[89][109][110] Opponents of the heavy launch vehicle have critically used the name "Senate launch system".[52] The Competitive Space Task Force, in September 2011, said that the new government launcher directly violates NASA’s charter, the Space Act, and the 1998 Commercial Space Act requirements for NASA to pursue the "fullest possible engagement of commercial providers" and to "seek and encourage, to the maximum extent possible, the fullest commercial use of space".[88]

Phil Plait has voiced his criticism of SLS in light of ongoing budget tradeoffs between Commercial Crew Development and SLS budget, also referring to earlier critique by Lori Garver.[111] Garver, former NASA Deputy Administrator, has called for cancelling the program.[112] Chris Kraft, the legendary NASA mission control leader from Apollo era, has expressed his criticism of the system as well.[113]

SLS program mission schedule

List only includes relatively near missions; more missions are planned than are listed below.

Confirmed SLS missions (Launch history)
Mission Acronym Rocket Manned Launch Date Result Duration Remarks Reference
Space Launch System 1 /
Exploration Mission 1 		SLS-1 / EM-1 SLS Block I No By November 2018 Planned Send unmanned Orion capsule on trip around the Moon, deploy Near-Earth Asteroid Scout, Lunar Flashlight, BioSentinel, SkyFire, Lunar IceCube, and 6 other small CubeSats.[114][115] [5][116]
Space Launch System 2 /
Exploration Mission 2 		SLS-2 / EM-2 SLS Block IB Yes 2021–2023 Planned Send an Orion capsule with four crew members in retrograde lunar orbit. [54][117][118][119]
Europa Multiple-Flyby Mission EMFM SLS Block IB No 2021-2025 Planned Send Europa probe and a lander to Jupiter. [120][121]
Space Launch System 3 /
Exploration Mission 3 		SLS-3 / EM-3 SLS Block IB Yes 2026 Planned Send an Orion capsule in 2026 with four crew members to an asteroid that had been robotically captured and placed in lunar orbit in late 2025 (Asteroid Redirect Mission). [122][123]

Proposed missions

Some of the currently proposed NASA Design Reference Missions (DRM) and others include:[23][66][124][125][126]

An astronaut, possibly part of Exploration Mission 2, performing a tethering asteroid capture maneuver at a near-earth object (NEO). The Space Exploration Vehicle is close by, with the Orion Multi-Purpose Crew Vehicle (MPCV) docked to the Deep Space Habitat in the background.
  • ISS Back-Up Crew Delivery – a single launch mission of up to four astronauts via a Block 1 SLS/Orion-MPCV without an Interim Cryogenic Propulsion Stage (ICPS) to the International Space Station (ISS) if the Commercial Crew Development program does not come to fruition. This potential mission mandated by the NASA Authorization Act of 2010 is deemed undesirable since the 70 t SLS and BEO Orion would be overpriced and overpowered for the mission requirements. Its current description is "delivers crew members and cargo to ISS if other vehicles are unable to perform that function. Mission length 216 mission days. 6 crewed days. Up to 210 days at the ISS."
  • Uranus orbiter and probe, SLS has been proposed by Boeing as a launch vehicle for a Uranian probe. The rocket would "Deliver a small payload into orbit around Uranus and a shallow probe into the planet’s atmosphere." The mission would study the Uranian atmosphere, magnetic and thermal characteristics, gravitational harmonics as well as do flybys of Uranian moons.[127][128]
  • Titan Saturn System Mission, SLS has been proposed as a launch vehicle for a probe to Saturn and its moons.[129]
    Artist's rendering of the Deep Space Habitat
One section of the Skylab II Habitat would be made from the SLS Block 2 upper-stage hydrogen tank, similar to but larger than Skylab. A unique use for the SLS as no other vehicle is presently being designed with an 8-meter-diameter upper stage tank.
Artist's rendering of the proposed Mars Transfer Vehicle (MTV) "Searcher" that would incorporate NTR propulsion and inflatable habitat technology. A crewed Orion MPCV is docked on the right.
  • Strategic timeframe DRMs
    • GEO mission – a dual-launch mission separated by 180 days to geostationary orbit. The first launch would comprise an SLS with a CPS and cargo hauler, the second an SLS with a CPS and Orion MPCV. Both launches would have a mass of about 110 t.[citation needed]
    • A set of lunar missions enabled in the early 2020s ranging from Earth-Moon Lagrangian point-1 (EML-1) and low lunar orbit (LLO) to a lunar surface mission. These missions would lead to a lunar base combining commercial and international aspects.
      • The lunar surface mission set for the late 2020s would be a dual launch separated by 120 days. This would be a 19-day mission with seven days on the Moon's surface. The first launch would comprise an SLS with a CPS and lunar lander, the second an SLS with a CPS and Orion MPCV. Both would enter LLO for lunar-orbit rendezvous prior to landing at equatorial or polar sites on the Moon. Launches would have masses of about 130 t and 108 t, respectively. Its current description is "Lunar Surface Sortie (LSS): Lands four crew members on the surface of the Moon in the equatorial or polar regions and returns them to Earth," "Expected drivers include: MPCV operations in LLO environment, MPCV uncrewed ops phase, MPCV delta V requirements, RPOD (rendezvous, proximity operations and docking), MPCV number of habitable days.”
    • Five Near Earth Asteroid (NEA) missions ranging from "minimum" to "full" capability are being studied. Among these are two NASA Near Earth Object (NEO) missions in 2026. A 155-day mission to NEO 1999 AO10, a 304-day mission to NEO 2001 GP2, a 490-day mission to a potentially hazardous asteroid such as 2000 SG344, utilizing two Block 1B SLS vehicles,[130] and a Boeing-proposed NEO mission to NEA 2008 EV5 in 2024. The latter would start from the proposed Earth-Moon L2 based Exploration Gateway Platform. Utilising an SLS third stage the trip would take about 100 days to arrive at the asteroid, 30 days for exploration, and a 235-day return trip to Earth.[131]
    • Forward Work Martian Moon Phobos/Deimos, a crewed flexible path mission to one of the Martian moons. It would include 40 days in the vicinity of Mars and a return Venus flyby.
    • Forward Work Mars Landing, a crewed mission, with four to six astronauts,[132] to a semi-permanent habitat for at least 540 days on the surface of the red planet in 2033 or 2045. The mission would include in-orbit assembly, with the launch of seven SLS Block 2 heavy-lift vehicles (HLVs). The seven HLV payloads, three of which would contain nuclear propulsion modules, would be assembled in LEO into three separate vehicles for the journey to Mars; one cargo In-Situ Resource Utilization Mars Lander Vehicle (MLV) created from two HLV payloads, one Habitat MLV created from two HLV payloads and a crewed Mars Transfer Vehicle (MTV), known as "Copernicus", assembled from three HLV payloads launched a number of months later. Nuclear Thermal Rocket engines such as the Pewee of Project Rover were selected in the Mars Design Reference Architecture (DRA) study as they met mission requirements being the preferred propulsion option because it uses proven technology, has higher performance, lower launch mass, creates a versatile vehicle design, offers simple assembly, and has growth potential.[66][133]
One proposed ATLAST concept, a design based on an 8-meter monolithic mirror. The Hubble Space Telescope by comparison is equipped with a 2.5 m main mirror. A telescope with an 8-meter monolithic mirror is possible only with a payload fairing bigger than 8 meters in diameter.
  • Other proposed missions
    • 2024+ Single Shot MSR on SLS, a crewed flight with a telerobotic Mars Sample Return (MSR) mission proposed by NASA's Mars Program Planning Group. The time frame suggests SLS-5, a 105 t rocket to deliver an Orion capsule, SEP robotic vehicle, and Mars Ascent Vehicle (MAV). "Sample canister could be captured, inspected, encased and retrieved tele-robotically. Robot brings sample back and rendezvous with a crew vehicle." The mission may also include a "Possible Mars SEP (Solar Electric Power/Propulsion) Orbiter".[134]
    • Potential sample return missions to Europa and Enceladus have also been noted.[135]
    • Deep Space Habitat (DSH), NASA's planned usage of spare ISS hardware, experience, and modules for future missions to asteroids, Earth-Moon Lagrangian point and Mars.[136]
    • Skylab II, proposal by Brand Griffin, an engineer with Gray Research Inc working with NASA Marshall, to use the upper stage hydrogen tank from SLS to build a 21st-century version of Skylab for future NASA missions to asteroids, Earth-Moon Lagrangian point-2 (EML2) and Mars.[137][138][139]
    • High Altitude Venus Operational Concept, a manned Venus mission using two SLS Block 1B launches to send a crew of 2 to explore the atmosphere of Venus for 1 month, with retrieval in Earth orbit by a commercial crew vehicle or an Orion.[140][141][142][143]
    • SLS DoD Missions, the HLV will be made available for U.S. Department of Defense and other US government agencies to launch military or classified missions.[citation needed]
    • Commercial payloads, such as the BA-330 have also been referenced.[128]
    • Additionally "secondary payloads" mounted on SLS via an Encapsulated Secondary Payload Adapter (ESPA) ring may also be launched in conjunction with a "primary passenger" to maximize payloads.
    • Advanced Technology Large-Aperture Space Telescope, SLS has been proposed by Boeing as a launch vehicle for the Advanced Technology Large-Aperture Space Telescope (ATLAST). This could be an 8 m monolithic telescope or a 16 m deployable telescope at Earth-Sun L2.[127]
    • Asteroid Deflection Mission, SLS could be used as a launch vehicle for emergency asteroid defense.[128]

Payload mass to various orbits

This includes cancelled/proposed SLS variants.

Vehicle Orbit or location Payload mass
(metric tons)		 Example mission Reference
Delta IV Heavy Low-Earth Orbit 28.79 Comparison only
Vulcan-561 Low-Earth Orbit 30.5 Comparison only [144]
Vulcan-500 Heavy Low-Earth Orbit 46.5 Comparison only [144]
Falcon Heavy Low-Earth Orbit 53 Comparison only [145]
Falcon Heavy Geostationary transfer orbit (GTO) 21.2 Comparison only [145]
Falcon Heavy Mars 13.2 Comparison only [145]
Block 0 Low-Earth Orbit 70 Send payloads to Low-Earth orbit, launch an Orion capsule and cargo to the International Space Station if Commercial Crew Development does not come to fruition [146]
Block I Low-Earth Orbit 93.1 Send payloads to Low-Earth orbit [128]
Block I Earth-Moon L-2 28 Send Orion capsule beyond the Moon, launch BA-330, Exploration Gateway Platform [128]
Block I Near-Earth object 12 Asteroid Redirect Mission [128]
Block I Lunar orbit 12 Visit captured asteroid [128]
Block I Jupiter 4 Europa Clipper, Jupiter orbiter followup to Galileo [128][129]
N1 Low-Earth Orbit 95 Comparison only
Energia Low-Earth Orbit 100 Comparison only
Block IA Low-Earth Orbit 105 Send payloads to Low-Earth orbit, preparation for human mission to Mars [147][148][146]
Block IB Low-Earth Orbit 105 Send payloads to Low-Earth orbit, preparation for human mission to Mars [128]
Block IB Trans-lunar injection 39.2 Human-assisted Lunar sample return [128]
Block IB Earth-Moon L-2 45 Crewed lunar surface mission, launch BA-330, Exploration Gateway Platform, Skylab II, Deep Space Habitat, or Nautilus-X, launch Orion and logistics module to these space stations [128]
Block IB Earth-Sun L-2 40 Advanced Technology Large-Aperture Space Telescope [128][129]
Block IB Near-Earth object 40 Planetary defense [128]
Block IB Saturn 6 Titan Saturn System Mission [129]
Block IB Uranus 5 Uranus orbiter and probe [128][129]
Block II Low-Earth orbit 130 Preparation for human mission to Mars [128][129]
Block II 200 AU 2 Interstellar probe [128][129]
Saturn V Low-Earth Orbit 140 Comparison only [citation needed]

See also

Videos

  • Space Launch System Booster Passes Major Ground Test
  • Igniting the Booster Space Launch System

References

  1. ^ "NASA commits to $7 billion mega rocket, 2018 debut". CBS News. August 27, 2014. Retrieved March 13, 2015.
  2. ^ a b ANDY PASZTOR (September 7, 2011). "White House Experiences Sticker Shock Over NASA's Plans". The Wall Street Journal. Retrieved February 22, 2015.
  3. ^ a b "ESD Integration, Budget Availability Scenarios" (PDF). Space Policy Online. August 19, 2011. Retrieved September 15, 2011.
  4. ^ a b "NASA's huge new rocket may cost $500 million per launch". MSNBC. September 12, 2012.
  5. ^ a b c d "NASA Completes Key Review of World's Most Powerful Rocket in Support". NASA. Retrieved October 26, 2015.
  6. ^ a b c "NASA space launch system" (PDF). c. 2012.
  7. ^ a b The Congress of the United States. Congressional Budget Office, October 2006, pp. X,1,4,9. "The Apollo Saturn V launch vehicle had a lift capability of 140 metric tons to low Earth orbit."
  8. ^ http://www.gizmag.com/nasa-space-launch-system-sls-critical-design-review/38612/
  9. ^ http://www.space.com/12954-nasa-rocket-powerful-space-launch-system.html
  10. ^ "Space Launch System". aerospaceguide.net.
  11. ^ a b "The NASA Authorization Act of 2010". Featured Legislation. Washington DC, USA: United States Senate. July 15, 2010. Retrieved May 26, 2011.
  12. ^ a b Marcia Smith (September 14, 2011). "New NASA Crew Transportation System to Cost $18 Billion Through 2017". Space Policy Online. Retrieved September 15, 2011.
  13. ^ Bill Nelson, Kay Bailey Hutchison, Charles F. Bolden (September 14, 2011). Future of NASA Space Program. Washington, D.C.: Cspan.org.
  14. ^ "NASA Announces Key Decision For Next Deep Space Transportation System". NASA. May 24, 2011. Retrieved January 26, 2012.
  15. ^ "NASA Announces Design For New Deep Space Exploration System". NASA. September 14, 2011. Retrieved September 14, 2011.
  16. ^ "Press Conference on the Future of NASA Space Program". C-Span. September 14, 2011. Retrieved September 14, 2011.
  17. ^ Kenneth Chang (September 14, 2011). "NASA Unveils New Rocket Design". New York Times. Retrieved September 14, 2011.
  18. ^ Karl Tate (September 16, 2011). "Space Launch System: NASA's Giant Rocket Explained". Space.com. Retrieved January 26, 2012.
  19. ^ a b Stephen Clark (March 31, 2011). "NASA to set exploration architecture this summer". Spaceflight Now. Retrieved May 26, 2011.
  20. ^ Dwayne Day (November 25, 2013). "Burning thunder".
  21. ^ Thomas P. Stafford (1991). "America at the Threshold - Report of the Synthesis Group on America's Space Exploration Initiative". p. 31.
  22. ^ a b c d Chris Bergin (October 4, 2011). "SLS trades lean towards opening with four RS-25s on the core stage". NASASpaceflight.com. Retrieved January 26, 2012.
  23. ^ a b c "Acronyms to Ascent – SLS managers create development milestone roadmap". NASASpaceFlight.com. February 23, 2012. Retrieved April 9, 2012.
  24. ^ a b c d e Bergin, Chris. "Advanced Boosters progress towards a solid future for SLS". NasaSpaceFlight.com. Retrieved February 2015. {{cite web}}: Check date values in: |accessdate= (help)
  25. ^ "NASA's Space Launch System Program PDR: Answers to the Acronym". NASA. August 1, 2013. Retrieved August 3, 2013.
  26. ^ a b Foust, Jeff (August 27, 2014). "SLS Debut Likely To Slip to 2018". SpaceNews.com. Retrieved March 12, 2015.
  27. ^ Sloss, Philip. "NASA ready to power up the RS-25 engines for SLS". NASASpaceFlight.com. Retrieved March 10, 2015.
  28. ^ a b Bergin, Chris. "Stennis conducts SLS engine firing marking RS-25 return". NASASpaceflight.com. Retrieved January 2015. {{cite web}}: Check date values in: |accessdate= (help)
  29. ^ Chris Bergin (September 14, 2011). "SLS finally announced by NASA – Forward path taking shape". NASASpaceflight.com. Retrieved January 26, 2012.
  30. ^ "NASA's Space Launch System Core Stage Passes Major Milestone, Ready to Start Construction". Space Travel. December 27, 2012.
  31. ^ Chris Bergin (April 25, 2011). "SLS planning focuses on dual phase approach opening with SD HLV". NASASpaceflight.com. Retrieved January 26, 2012.
  32. ^ Bergin, Chris (June 16, 2011). "Managers SLS announcement after SD HLV victory". NASASpaceflight.com. Retrieved January 26, 2012.
  33. ^ Priskos, Alex. "Five-segment Solid Rocket Motor Development Status" (PDF). ntrs.nasa.gov. NASA. Retrieved March 11, 2015.
  34. ^ "Space Launch System: How to launch NASA's new monster rocket". NASASpaceFlight.com. February 20, 2012. Retrieved April 9, 2012.
  35. ^ "NASA and ATK Successfully Test Ares First Stage Motor". NASA. September 10, 2009. Retrieved January 30, 2012.
  36. ^ "NASA and ATK Successfully Test Five-Segment Solid Rocket Motor". NASA. August 31, 2010. Retrieved January 30, 2012.
  37. ^ NASA Successfully Tests Five-Segment Solid Rocket Motor, NASA, August 31, 2010, retrieved September 8, 2011
  38. ^ Bergin, Chris (March 10, 2015). "QM-1 shakes Utah with two minutes of thunder". NASASpaceFlight.com. Retrieved March 10, 2015.
  39. ^ Keith Cowing (September 14, 2011). "NASA's New Space Launch System Announced – Destination TBD". SpaceRef. Retrieved January 26, 2012.
  40. ^ Frank Morring (June 17, 2011). "NASA Will Compete Space Launch System Boosters". Aviation Week. Retrieved June 20, 2011.
  41. ^ "NASA's Space Launch System: Partnering For Tomorrow" (PDF). NASA. Retrieved March 12, 2013.
  42. ^ Rachel Kraft (February 14, 2013). "NASA Awards Final Space Launch System Advanced Booster Contract". NASA. Retrieved February 19, 2013.
  43. ^ "The Dark Knights – ATK's Advanced Boosters for SLS revealed". January 14, 2013.
  44. ^ "Table 2. ATK Advanced Booster Satisfies NASA Exploration Lift Requirements".
  45. ^ Lee Hutchinson (April 15, 2013). "New F-1B rocket engine upgrades Apollo-era design with 1.8M lbs of thrust". Ars Technica. Retrieved April 15, 2013.
  46. ^ "Dynetics reporting "outstanding" progress on F-1B rocket engine". Ars Technica. August 13, 2013. Retrieved August 13, 2013.
  47. ^ Lee Hutchinson (April 15, 2013). "New F-1B rocket engine upgrades Apollo-era design with 1.8M lbs of thrust". Ars Technica. Retrieved April 15, 2013.
  48. ^ "Dynetics PWR liquidize SLS booster competition". November 2012.
  49. ^ "SLS Block II drives hydrocarbon engine research". thespacereview.com. January 14, 2013.
  50. ^ http://www.nasaspaceflight.com/2012/07/wind-tunnel-testing-sls-configurations-block-1b/
  51. ^ "News from the 30th Space Symposium | Second SLS Mission Might Not Carry Crew". spacenews.com. May 21, 2014. Retrieved July 2014. {{cite web}}: Check date values in: |accessdate= (help)
  52. ^ a b Rosenberg, Zach. "Delta second stage chosen as SLS interim". Flight International, May 8, 2012.
  53. ^ "Space Launch System Data Sheet". SpaceLaunchReport.com. Retrieved July 25, 2014.
  54. ^ a b "NASA confirms EUS for SLS Block 1B design and EM-2 flight". NASASpaceflight.com. Retrieved July 24, 2014.
  55. ^ a b "SLS prepares for PDR – Evolution eyes Dual-Use Upper Stage". NASASpaceFlight.com. Retrieved March 12, 2015.
  56. ^ Chris Bergin (November 9, 2011). "SLS J-2X Upper Stage engine enjoys successful 500 second test fire". nasaspaceflight.com.
  57. ^ Chris Bergin (February 12, 2013). "Second J-2X engine prepares for SLS testing". nasaspaceflight.com.
  58. ^ http://www.space-travel.com/reports/NASA_Researchers_Studying_Advanced_Nuclear_Rocket_Technologies_999.html
  59. ^ "NUCLEAR ROCKETS: To Mars and Beyond Nuclear Rockets: Then and Now. LANL".
  60. ^ "How long would a trip to Mars take?".
  61. ^ "How Fast Could (Should) We Go to Mars? Comparing Nuclear Electric Propulsion (NEP) with the Nuclear Thermal Rocket (NTR) and Chemical Rocket for Sustainable 1-year human Mars round-trip mission".
  62. ^ a b "A One-year Round Trip Crewed Mission to Mars using Bimodal Nuclear Thermal and Electric Propulsion (BNTEP) (doi: 10.2514/6.2013-4076)".
  63. ^ Borowski, Stanley K.; McCurdy, David R.; Packard, Thomas W. (April 9, 2012). "Nuclear Thermal Propulsion (NTP): A Proven Growth Technology for Human NEO / Mars Exploration Missions" (PDF). NASA.
  64. ^ Borowski, Stanley K.; McCurdy, David R.; Packard, Thomas W. (August 16, 2012). "Nuclear Thermal Rocket/Vehicle Characteristics And Sensitivity Trades For NASA's Mars Design Reference Architecture (DRA) 5.0 Study" (PDF). NASA.
  65. ^ "Nuclear Thermal Propulsion (NTP): A Proven Growth Technology for Human NEO / Mars Exploration Missions" (PDF). 2012.
  66. ^ a b c Chris Bergin (January 24, 2012). "SLS Exploration Roadmap evaluations provide clues for human Mars missions". NASASpaceflight.com. Retrieved January 26, 2012.
  67. ^ "NASA Researchers Studying Advanced Nuclear Rocket Technologies by Rick Smith for Marshall Space Flight Center, Huntsville AL (SPX) Jan 10, 2013".
  68. ^ Chris Gebhardt (November 13, 2013). "SLS upper stage proposals reveal increasing payload-to-destination options". nasaspaceflight.com.
  69. ^ http://seradata.com/SSI/2013/06/sls-may-change-upper-stage-eng/
  70. ^ http://seradata.com/SSI/2014/11/next-steps-for-sls-europes-vinci-is-a-contender-for-exploration-upper-stage-engine/
  71. ^ Casey Dreier (July 21, 2014). "A generational opportunity for Europa".
  72. ^ SLS Engine Section Barrel Hot off the Vertical Weld Center at Michoud. NASA
  73. ^ "SLS to be robust in the face of scrubs, launch delays and pad stays". NASASpaceFlight.com. April 4, 2012. Retrieved April 9, 2012.
  74. ^ "NASA facilities, teams ramp up SLS flight production for 2018 maiden flight". NASASpaceflight.com. Retrieved January 2016. {{cite web}}: Check date values in: |accessdate= (help)
  75. ^ Davis, Jason. "NASA Budget Lists Timelines, Costs and Risks for First SLS Flight". The Planetary Society. Retrieved March 11, 2015.
  76. ^ "Independent Cost Assessment of the Space Launch System, Multi-purpose Crew Vehicle and 21st Century Ground Systems Programs: Executive Summary of Final Report" (PDF). Booz Allen Hamilton. NASA.gov. August 19, 2011.
  77. ^ Marcia Smith (September 9, 2011). "The NASA Numbers Behind That WSJ Article". Space Policy Online. Retrieved September 15, 2011.
  78. ^ "HEFT Phase I Closeout" (PDF). nasawatch.com. September 2010. p. 69.
  79. ^ Chris Bergin (October 4, 2011). "SLS trades lean towards opening with four RS-25s on the core stage". NASA Spaceflight.com. Retrieved September 16, 2013.
  80. ^ Lee Roop (July 29, 2013). "NASA defends Space Launch System against charge it 'is draining the lifeblood' of space program". Alabama local news. Retrieved February 18, 2015.
  81. ^ John Strickland (July 15, 2013). "Revisiting SLS/Orion launch costs". The Space Review. Retrieved February 18, 2015.
  82. ^ NASA Signs Agreement for a European-Provided Orion Service Module
  83. ^ "SP-4221 The Space Shuttle Decision- Chapter 6: ECONOMICS AND THE SHUTTLE". NASA. Retrieved January 15, 2011.
  84. ^ The Apollo Spacecraft: A Chronology, volumes I through IV.
  85. ^ Consumer Price Index (Estimate) 1800- Source: Handbook of Labor Statistics U.S. Department of Labor Bureau of Labor Statistics Indexes from 1800 to 1912 and 2015 estimated
  86. ^ Morrison, Lauren; Bale, Lauren (July 24, 2014). "Federal audit reveals not enough money for NASA to get SLS off the ground". 48 WAFF.{{cite web}}: CS1 maint: multiple names: authors list (link)
  87. ^ Clark, Stephen (December 14, 2014). "NASA gets budget hike in spending bill passed by Congress". Spaceflight Now. Retrieved December 15, 2014.
  88. ^ a b c Henry Vanderbilt (September 15, 2011). "Impossibly High NASA Development Costs Are Heart of the Matter". moonandback.com. Retrieved January 26, 2012.
  89. ^ a b Ferris Valyn (September 15, 2011). "Monster Rocket Will Eat America's Space Program". Space Frontier Foundation. Retrieved September 16, 2011.
  90. ^ "Statement before the Committee on Science, Space, and Technology US House of Representatives Hearing: A Review of the NASA's Space Launch System" (PDF). The Planetary Society. July 12, 2011. Retrieved January 26, 2012.
  91. ^ Rohrabacher, Dana (September 14, 2011). "Nothing New or Innovative, Including It's Astronomical Price Tag". Retrieved September 14, 2011.
  92. ^ "Rohrabacher calls for "emergency" funding for CCDev". parabolicarc.com. August 24, 2011. Retrieved September 15, 2011.
  93. ^ Jeff Foust (September 15, 2011). "A monster rocket, or just a monster?". The Space Review.
  94. ^ Jeff Foust (November 1, 2011). "Can NASA develop a heavy-lift rocket?". The Space Review.
  95. ^ Mohney, Doug (October 21, 2011). "Did NASA Hide In-space Fuel Depots To Get a Heavy Lift Rocket?". Satellite Spotlight. Retrieved November 10, 2011.
  96. ^ "Propellant Depot Requirements Study" (PDF). HAT Technical Interchange Meeting. July 21, 2011.
  97. ^ Cowing, Keith (October 12, 2011). "Internal NASA Studies Show Cheaper and Faster Alternatives to the Space Launch System". SpaceRef.com. Retrieved November 10, 2011.
  98. ^ "Near Term Space Exploration with Commercial Launch Vehicles Plus Propellant Depot" (PDF). Georgia Institute of Technology / National Institute of Aerospace. 2011.
  99. ^ "Affordable Exploration Architecture" (PDF). United Launch Alliance. 2009.
  100. ^ Grant Bonin (June 6, 2011). "Human spaceflight for less: the case for smaller launch vehicles, revisited". The Space Review.
  101. ^ Robert Zubrin (May 14, 2011). "How We Can Fly to Mars in This Decade—And on the Cheap". Mars Society.
  102. ^ Rick Tumlinson (September 15, 2011). "The Senate Launch System – Destiny, Decision, and Disaster". Huffington Post.
  103. ^ Andrew Gasser (October 24, 2011). "Propellant depots: the fiscally responsible and feasible alternative to SLS". The Space Review.
  104. ^ Review of U.S. Human Space Flight Plans Committee; Augustine, Austin; Chyba, Kennel; Bejmuk, Crawley; Lyles, Chiao; Greason, Ride (October 2009). "Seeking A Human Spaceflight Program Worthy of A Great Nation" (PDF). NASA. Retrieved April 15, 2010.
  105. ^ Alan Boyle (December 7, 2011). "Is the case for Mars facing a crisis?". MSNBC. Archived from the original on January 7, 2012. {{cite web}}: Unknown parameter |deadurl= ignored (|url-status= suggested) (help)
  106. ^ John K. Strickland, Jr. "The SpaceX Falcon Heavy Booster: Why Is It Important?". National Space Society. Retrieved January 4, 2012.
  107. ^ "NASA Studies Scaled-Up Falcon, Merlin". Aviation Week. December 2, 2010.
  108. ^ Bergin, Chris (August 29, 2014). "Battle of the Heavyweight Rockets -- SLS could face Exploration Class rival". NASAspaceflight.com. Retrieved August 30, 2014.
  109. ^ "Congressman, Space Frontier Foundation, And Tea Party In Space Call For NASA SLS Investigation". moonandback.com. October 4, 2011. Retrieved October 20, 2011.
  110. ^ "The Senate Launch System". Competitive Space. October 4, 2011. Retrieved October 20, 2011.
  111. ^ "Why NASA Still Can't Put Humans in Space: Congress Is Starving It of Needed Funds".
  112. ^ "Garver: NASA Should Cancel SLS and Mars 2020 Rover". Space News.
  113. ^ "NASA veteran Chris Kraft upfront with criticism".
  114. ^ https://www.youtube.com/watch?v=oGKry-AmV-c
  115. ^ http://www.jpl.nasa.gov/cubesat/missions/neascout.php
  116. ^ "Acronyms to Ascent – SLS managers create development milestone roadmap". Retrieved October 26, 2015.
  117. ^ "First Crewed Orion Mission May Slip to 2023". SpaceNews.com. Retrieved October 26, 2015.
  118. ^ "NASA's 1st Manned Flight of Orion Space Capsule May Slip to 2023". Space.com. Retrieved October 26, 2015.
  119. ^ "NASA's Human Spaceflight Program Moves Forward - APPEL – Academy of Program/Project & Engineering Leadership". Retrieved October 26, 2015.
  120. ^ https://thespacereporter.com/2016/01/additional-1-3-billion-nasa-fund-next-mars-rover-europa-mission/
  121. ^ http://www.planetary.org/blogs/guest-blogs/van-kane/20160105-nasa-europa-lander.html
  122. ^ "NASA Advisory Council: Select a Human Exploration Destination ASAP". Retrieved October 26, 2015.
  123. ^ "NASA Selects Boulder Option for Asteroid Redirect Mission". SpaceNews.com. Retrieved October 26, 2015.
  124. ^ Chris Bergin (December 15, 2011). "Building the Roadmap for SLS – Con Ops lays out the LEO/Lunar Options". NASASpaceflight.com. Retrieved January 26, 2012.
  125. ^ "SLS interest in DoD launch market and Secondary Payloads potential". NASASpaceFlight.com. February 4, 2012. Retrieved April 9, 2012.
  126. ^ "NASA Exploration Roadmap: A return to the Moon's surface documented". NASASpaceFlight.com. March 19, 2012. Retrieved April 9, 2012.
  127. ^ a b Chris Gebhardt (November 20, 2013). "New SLS mission options explored via new Large Upper Stage". NASASpaceFlight.
  128. ^ a b c d e f g h i j k l m n o p http://www.boeing.com/assets/pdf/defense-space/space/sls/docs/sls_mission_booklet_jan_2014.pdf
  129. ^ a b c d e f g https://www.nasa.gov/sites/default/files/files/Creech_SLS_Deep_Space.pdf
  130. ^ "NASA managers evaluate yearlong deep space asteroid mission September 9, 2013 by Marshall Murphy".
  131. ^ http://www.nasaspaceflight.com/2012/11/long-duration-iss-crew-foundations-beo-missions/
  132. ^ Chris Bergin (October 6, 2013). "NASA Con Ops Assess Baseline Features for SLS/Orion Mission to Mars".
  133. ^ "Nuclear Thermal Propulsion (NTP): A Proven Growth Technology for Human NEO / Mars Exploration Missions" (PDF).
  134. ^ Chris Bergin (November 30, 2012). "NASA interest in 2024 Mars Sample Return Mission using SLS and Orion". NASASpaceFlight.com.
  135. ^ http://www.nasaspaceflight.com/2012/11/nasa-payload-fairings-options-multi-mission-sls-capability/
  136. ^ NASA's Deep Space Habitat
  137. ^ Markus Hammonds (April 14, 2013). "Skylab II:Living Beyong the Dark Side of the Moon". Discovery.
  138. ^ http://www.nasaspaceflight.com/2012/03/dsh-module-concepts-outlined-beo-exploration/
  139. ^ Frank Morring, Jr. (October 22, 2012). "NASA Deep-Space Program Gaining Focus". Aviation Week & Space Technology.
  140. ^ https://www.youtube.com/watch?v=0az7DEwG68A
  141. ^ http://sacd.larc.nasa.gov/branches/space-mission-analysis-branch-smab/smab-projects/havoc/
  142. ^ http://www.space.com/29141-venus-airship-havoc-nasa-concept-gallery.html
  143. ^ http://www.gizmag.com/nasa-havoc-concept-manned-mission-to-venus/35311/
  144. ^ a b http://www.ulalaunch.com/products_vulcan.aspx
  145. ^ a b c http://www.spacex.com/falcon-heavy
  146. ^ a b http://www.spacelaunchreport.com/sls0.html
  147. ^ http://www.nasa.gov/pdf/623766main_8143_Singer-AD_industry_day-021312_FINAL3.pdf
  148. ^ http://www.nasaspaceflight.com/2012/03/sls-specifications-take-shape-development-continues/
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