James Webb Space Telescope
This article documents a current or recent spaceflight. Details may change as the mission progresses. Initial news reports may be unreliable. The last updates to this article may not reflect the most current information. For more information please see WikiProject Spaceflight. |
Names | Next Generation Space Telescope (NGST; 1996–2002) |
---|---|
Mission type | Astronomy |
Operator | STScI (NASA)[1] |
COSPAR ID | 2021-130A |
SATCAT no. | 50463[2] |
Website | Official website |
Mission duration | |
Spacecraft properties | |
Manufacturer | |
Launch mass | 6,161.4 kg (13,584 lb)[5] |
Dimensions | 20.197 m × 14.162 m (66.26 ft × 46.46 ft), sunshield |
Power | 2 kW |
Start of mission | |
Launch date | 25 December 2021UTC | , 12:20
Rocket | Ariane 5 ECA (VA256) |
Launch site | Centre Spatial Guyanais, ELA-3 |
Contractor | Arianespace |
Orbital parameters | |
Reference system | Sun–Earth L2 orbit |
Regime | Halo orbit |
Periapsis altitude | 250,000 km (160,000 mi)[6] |
Apoapsis altitude | 832,000 km (517,000 mi)[6] |
Period | 6 months |
Main telescope | |
Type | Korsch telescope |
Diameter | 6.5 m (21 ft) |
Focal length | 131.4 m (431 ft) |
Focal ratio | f/20.2 |
Collecting area | 25.4 m2 (273 sq ft)[7] |
Wavelengths | 0.6–28.3 μm (orange to mid-infrared) |
Transponders | |
Band | |
Bandwidth |
|
Instruments | |
Elements | |
James Webb Space Telescope mission logo |
The James Webb Space Telescope (JWST) is a space telescope and an international collaboration among NASA, the European Space Agency (ESA), and the Canadian Space Agency (CSA).[8] The telescope is named after James E. Webb,[9] who was the administrator of NASA from 1961 to 1968 and played an integral role in the Apollo program.[10][11] It is intended to succeed the Hubble Space Telescope as NASA's flagship mission in astrophysics.[12][13] JWST was launched December 25, 2021 on Ariane flight VA256. It is designed to provide improved infrared resolution and sensitivity over Hubble, viewing objects up to 100 times fainter[14] and will enable a broad range of investigations across the fields of astronomy and cosmology, including observations up to redshift z≈20[14] of some of the oldest, most distant, events and objects in the Universe such as the first stars and formation of the first galaxies, and allowing detailed atmospheric characterization of potentially habitable exoplanets.
JWST's primary mirror, the Optical Telescope Element, consists of 18 hexagonal mirror segments made of gold-plated beryllium which combine to create a 6.5-meter (21 ft)[15] diameter mirror. This gives Webb's telescope a light collecting area about 5.6 times as large as Hubble's 2.4 m (7.9 ft) mirror (25.37 m2 collecting area to Hubble's 4.525 m2). Unlike Hubble, which observes in the near ultraviolet, visible, and near infrared (0.1–1.0 μm) spectra, JWST will observe in a lower frequency range, from long-wavelength visible light (red) through mid-infrared (0.6–28.3 μm). This will enable it to observe high-redshift objects that are too old, faint, and distant for Hubble.[16][17] The telescope must be kept below 50 K (−223 °C; −370 °F) to observe faint signals in the infrared without interference from any other sources of warmth, so it will be deployed in space near the Sun–Earth L2 Lagrange point, a point in space about 1.5 million kilometers (930,000 mi) from Earth, where its 5 layer kite-shaped sunshield can protect it from warming by the Sun, Earth and Moon at the same time.[18][19]
The NASA Goddard Space Flight Center (GSFC) in Maryland managed the development and the Space Telescope Science Institute is operating JWST.[20] The prime contractor was Northrop Grumman.[21]
Development began in 1996 for a launch that was initially planned for 2007 with a US$500 million budget.[22] There were many delays and cost overruns, including a major redesign in 2005,[23] a ripped sunshield during a practice deployment, a recommendation from an independent review board, the COVID-19 pandemic,[24][25][26] issues with the Ariane 5 rocket[27] and the telescope itself, and communications issues between the telescope and the launch vehicle.[28] The high-stakes nature of the launch and the telescope's complexity was remarked upon by the media, and commented on by scientists and engineers.[29][30]
Construction was completed in late 2016, when an extensive testing phase began.[31][32] JWST was launched 12:20 UTC 25 December 2021[33] by an Ariane 5 launch vehicle from Kourou, French Guiana and was released from the upper stage 27 minutes later.[34] The launch was described by NASA as "flawless" and "perfect".[35] As of 8 January 2022[update], the telescope has been fully and successfully unfolded to its operational configuration,[36][37] and continues to travel to its target destination.[38][39][40] It will take several weeks to cool to its operational temperature, and will then undergo final testing and calibration procedures for around 5 months, potentially including its first images,[41][42] before commencing its planned research program.[43][44]
Features
The James Webb Space Telescope has a mass about half of Hubble Space Telescope's, but a 6.5 m (21 ft)-diameter gold-coated beryllium primary mirror made of 18 hexagonal mirrors, giving it a total size over six times as large as Hubble's 2.4-metre (7.9 ft). Of this, 0.9 m2 (9.7 sq ft) is obscured by the secondary support struts,[45] making its actual light collecting area about 5.6 times larger than Hubble's 4.525 m2 (48.71 sq ft) collecting area. Beryllium is a very stiff, hard, lightweight metal often used in aerospace that is non-magnetic and keeps its shape accurately in an ultra-cold environment.[46] The gold coating provides infrared reflectivity and durability.
JWST is designed primarily for near-infrared astronomy, but can also see orange and red visible light, as well as the mid-infrared region, depending on the instrument. It can detect objects up to 100 times fainter than Hubble, and objects much earlier in the history of the universe, back to redshift z≈20 (about 180 million years cosmic time (after the Big Bang)).[14] For comparison, the earliest stars are thought to have formed between z≈30 and z≈20 (100-180 million years cosmic time),[47] the first galaxies may have formed around redshift z≈15 (about 270 million years cosmic time), and Hubble is unable to see further back than very early reionization[48][49] at about z≈11.1 (galaxy GN-z11, 400 million years cosmic time).[50][51][14]
The design emphasizes the near to mid-infrared for three main reasons:
- high-redshift (very old and distant) objects have their visible emissions shifted into the infrared, and therefore their light can only be observed today via infrared astronomy;
- colder objects such as debris disks and planets emit most strongly in the infrared;
- these infrared bands are difficult to study from the ground or by existing space telescopes such as Hubble.
Ground-based telescopes must look through Earth's atmosphere, which is opaque in many infrared bands (see figure of atmospheric absorption). Even where the atmosphere is transparent, many of the target chemical compounds, such as water, carbon dioxide, and methane, also exist in the Earth's atmosphere, vastly complicating analysis. Existing space telescopes such as Hubble cannot study these bands since their mirrors are insufficiently cool (the Hubble mirror is maintained at about 15 °C (288 K; 59 °F)) thus the telescope itself radiates strongly in the infrared bands.[52]
JWST can also observe nearby objects, including objects in our own solar system, having an apparent angular rate of motion of 0.030 arc seconds per second or less. This includes all planets and satellites, comets, and asteroids beyond Earth's orbit, and "virtually all" known Kuiper Belt Objects.[47] In addition, it can observe opportunistic and unplanned targets within 48 hours of a decision to do so, such as supernovae and gamma ray bursts.[47]
JWST will operate in a halo orbit, circling around a point in space known as the Sun-Earth L2 Lagrange point, approximately 1,500,000 km (930,000 mi) beyond Earth's orbit around the Sun. Its actual position will vary between about 250,000 km (160,000 mi) and 832,000 km (517,000 mi) from L2 as it orbits, keeping it out of both Earth and Moon's shadow. By way of comparison, Hubble orbits 550 km (340 mi) above Earth's surface, and the Moon is roughly 400,000 km (250,000 mi) from Earth. Objects near this Sun-Earth L2 point can orbit the Sun in synchrony with the Earth, allowing the telescope to remain at a roughly constant distance[53] with continuous orientation of its unique sunshield and equipment bus toward the Sun, Earth and Moon. Combined with its wide shadow-avoiding orbit, the telescope can simultaneously block incoming heat and light from all three of these bodies and avoid even the smallest changes of temperature from Earth and Moon shadows that would affect the structure, yet still maintain uninterrupted solar power and Earth communications on its sun-facing side. This arrangement will keep the temperature of the spacecraft constant and below the 50 K (−223 °C; −370 °F) necessary for faint infrared observations.[19][54]
JWST is currently (as of 2021[update]) not intended to be serviced in space. A crewed mission to repair or upgrade the observatory, as was done for Hubble, would be impossible,[55] and according to NASA Associate Administrator Thomas Zurbuchen, despite best efforts, an unmanned remote mission was found to be beyond current technology at the time JWST was designed.[56] During the long JWST testing period, NASA officials referred to the idea of a servicing mission, but no plans were announced.[57][58] Since the successful launch, NASA have stated that limited accommodation was made to facilitate future servicing missions, if any. This included: precise guidance markers in the form of crosses on the surface of JWST, for use by remote servicing missions, as well as refillable fuel tanks, removable heat protectors, and accessible attachment points.[59][56]
-
Three-quarter view of the top
-
Bottom (Sun-facing side)
Sunshield protection
To make observations in the infrared spectrum, JWST must be kept under 50 K (−223.2 °C; −369.7 °F); otherwise, infrared radiation from the telescope itself would overwhelm its instruments. It therefore uses a large sunshield to block light and heat from the Sun, Earth, and Moon, and its position near the Sun-Earth L2 keeps all three bodies on the same side of the spacecraft at all times.[60] Its halo orbit around the L2 point avoids the shadow of the Earth and Moon, maintaining a constant environment for the sunshield and solar arrays.[53] The shielding maintains a stable temperature for the structures on the dark side, which is critical to maintaining precise alignment of the primary mirror segments in space.[19]
The five-layer sunshield, each layer as thin as a human hair,[61] is constructed from Kapton E, a commercially available polyimide film from DuPont, with membranes specially coated with aluminum on both sides and a layer of doped silicon on the Sun-facing side of the two hottest layers to reflect the Sun's heat back into space.[19] Accidental tears of the delicate film structure during testing in 2018 were among the factors delaying the project.[62]
The sunshield was designed to be folded twelve times so that it fit within the Ariane 5 rocket's payload fairing, which is 4.57 m (15.0 ft) in diameter, and 16.19 m (53.1 ft) long. The shield's fully deployed dimensions were planned as 14.162 m × 21.197 m (46.46 ft × 69.54 ft). The sunshield was hand-assembled at ManTech (NeXolve) in Huntsville, Alabama, before it was delivered to Northrop Grumman in Redondo Beach, California, for testing.[63]
Because of the sunshield, JWST does not have an unlimited field of regard at any given time. The telescope can see 40 percent of the sky from one position and can see all of the sky over a period of six months,[64] the amount of time it takes to complete half its orbit around the Sun.
Optics
JWST's primary mirror is a 6.5 m (21 ft)-diameter gold-coated beryllium reflector with a collecting area of 25.4 m2 (273 sq ft). If it were built as a single large mirror, this would have been too large for existing launch vehicles. The mirror is therefore composed of 18 hexagonal segments (Guido Horn d'Arturo's multi-mirror telescope), which unfolded after the telescope was launched. Image plane wavefront sensing through phase retrieval is used to position the mirror segments in the correct location using very precise micro-motors. Subsequent to this initial configuration, they only need occasional updates every few days to retain optimal focus.[65] This is unlike terrestrial telescopes, for example the Keck telescopes, which continually adjust their mirror segments using active optics to overcome the effects of gravitational and wind loading. The Webb telescope will use 126 small motors to occasionally adjust the optics as there are few environmental disturbances of a telescope in space.[66]
JWST's optical design is a three-mirror anastigmat,[67] which makes use of curved secondary and tertiary mirrors to deliver images that are free from optical aberrations over a wide field. The secondary mirror is 0.74 m (2.4 ft) diameter. In addition, there is a fine steering mirror which can adjust its position many times per second to provide image stabilization. The primary mirror segments are hollowed at the rear in a honeycomb pattern, to reduce weight.
Ball Aerospace & Technologies is the principal optical subcontractor for the JWST project, led by prime contractor Northrop Grumman Aerospace Systems, under a contract from the NASA Goddard Space Flight Center, in Greenbelt, Maryland.[68][69] Eighteen primary mirror segments, secondary, tertiary and fine steering mirrors, plus flight spares have been fabricated and polished by Ball Aerospace & Technologies based on beryllium segment blanks manufactured by several companies including Axsys, Brush Wellman, and Tinsley Laboratories.[70]
Scientific instruments
The Integrated Science Instrument Module (ISIM) is a framework that provides electrical power, computing resources, cooling capability as well as structural stability to the Webb telescope. It is made with bonded graphite-epoxy composite attached to the underside of Webb's telescope structure. The ISIM holds the four science instruments and a guide camera.[71]
- NIRCam (Near InfraRed Camera) is an infrared imager which will have a spectral coverage ranging from the edge of the visible (0.6 μm) through to the near infrared (5 μm).[72][73] There are 10 sensors each of 4 megapixels. NIRCam will also serve as the observatory's wavefront sensor, which is required for wavefront sensing and control activities. NIRCam was built by a team led by the University of Arizona, with principal investigator Marcia J. Rieke. The industrial partner is Lockheed-Martin's Advanced Technology Center in Palo Alto, California.[74]
- NIRSpec (Near InfraRed Spectrograph) will also perform spectroscopy over the same wavelength range. It was built by the European Space Agency at ESTEC in Noordwijk, Netherlands. The leading development team includes members from Airbus Defence and Space, Ottobrunn and Friedrichshafen, Germany, and the Goddard Space Flight Center; with Pierre Ferruit (École normale supérieure de Lyon) as NIRSpec project scientist. The NIRSpec design provides three observing modes: a low-resolution mode using a prism, an R~1000 multi-object mode, and an R~2700 integral field unit or long-slit spectroscopy mode.[75] Switching of the modes is done by operating a wavelength preselection mechanism called the Filter Wheel Assembly, and selecting a corresponding dispersive element (prism or grating) using the Grating Wheel Assembly mechanism.[75] Both mechanisms are based on the successful ISOPHOT wheel mechanisms of the Infrared Space Observatory. The multi-object mode relies on a complex micro-shutter mechanism to allow for simultaneous observations of hundreds of individual objects anywhere in NIRSpec's field of view. There are two sensors each of 4 megapixels. The mechanisms and their optical elements were designed, integrated and tested by Carl Zeiss Optronics GmbH of Oberkochen, Germany, under contract from Astrium.[75]
- MIRI (Mid-InfraRed Instrument) will measure the mid-to-long-infrared wavelength range from 5 to 27 μm.[76][77] It contains both a mid-infrared camera and an imaging spectrometer.[68] MIRI was developed as a collaboration between NASA and a consortium of European countries, and is led by George Rieke (University of Arizona) and Gillian Wright (UK Astronomy Technology Centre, Edinburgh, Scotland, part of the Science and Technology Facilities Council (STFC)).[74] MIRI features similar wheel mechanisms to NIRSpec which are also developed and built by Carl Zeiss Optronics GmbH under contract from the Max Planck Institute for Astronomy, Heidelberg, Germany. The completed Optical Bench Assembly of MIRI was delivered to Goddard Space Flight Center in mid-2012 for eventual integration into the ISIM. The temperature of the MIRI must not exceed 6 K (−267 °C; −449 °F): a helium gas mechanical cooler sited on the warm side of the environmental shield provides this cooling.[78]
- FGS/NIRISS (Fine Guidance Sensor and Near Infrared Imager and Slitless Spectrograph), led by the Canadian Space Agency under project scientist John Hutchings (Herzberg Astronomy and Astrophysics Research Centre, National Research Council), is used to stabilize the line-of-sight of the observatory during science observations. Measurements by the FGS are used both to control the overall orientation of the spacecraft and to drive the fine steering mirror for image stabilization. The Canadian Space Agency is also providing a Near Infrared Imager and Slitless Spectrograph (NIRISS) module for astronomical imaging and spectroscopy in the 0.8 to 5 μm wavelength range, led by principal investigator René Doyon at the Université de Montréal.[74] Because the NIRISS is physically mounted together with the FGS, they are often referred to as a single unit; however, they serve entirely different purposes, with one being a scientific instrument and the other being a part of the observatory's support infrastructure.
NIRCam and MIRI feature starlight-blocking coronagraphs for observation of faint targets such as extrasolar planets and circumstellar disks very close to bright stars.[77]
The infrared detectors for the NIRCam, NIRSpec, FGS, and NIRISS modules are being provided by Teledyne Imaging Sensors (formerly Rockwell Scientific Company). The James Webb Space Telescope (JWST) Integrated Science Instrument Module (ISIM) and Command and Data Handling (ICDH) engineering team uses SpaceWire to send data between the science instruments and the data-handling equipment.[79]
Spacecraft bus
The spacecraft bus is the primary support component of the James Webb Space Telescope which hosts a multitude of computing, communication, electric power, propulsion, and structural parts.[80] Along with the sunshield, it forms the spacecraft element of the space telescope.[81] The other two major elements of JWST are the Integrated Science Instrument Module (ISIM) and the Optical Telescope Element (OTE).[82] Region 3 of ISIM is also inside the spacecraft bus; region 3 includes ISIM Command and Data Handling subsystem and the MIRI cryocooler.[82] The spacecraft bus is connected to Optical Telescope Element via the Deployable Tower Assembly, which also connects to the sunshield.[80] The spacecraft bus is on the Sun-facing "warm" side of the sunshield and operates at a temperature of about 300 K (27 °C; 80 °F).[81]
The structure of the spacecraft bus has a mass of 350 kg (770 lb), and must support the 6,200 kg (13,700 lb) space telescope.[83] It is made primarily of graphite composite material.[83] It was assembled in California, assembly was completed in 2015, and then it had to be integrated with the rest of the space telescope leading up to its 2021 launch. The spacecraft bus can rotate the telescope with a pointing precision of one arcsecond, and isolates vibration down to two milliarcseconds.[84]
In the central computing, memory storage, and communications equipment,[80] the processor and software direct data to and from the instruments, to the solid-state memory core, and to the radio system which can send data back to Earth and receive commands.[80] The computer also controls the pointing of the spacecraft, taking in sensor data from the gyroscopes and star tracker, and sending commands to the reaction wheels or thrusters.[80]
Webb has two pairs of rocket engines (one pair for redundancy) to make course corrections on the way to L2 and for station keeping—maintaining the correct position in the halo orbit. Eight smaller thrusters are used for attitude control—the correct pointing of the spacecraft.[85] The engines use hydrazine fuel (159 liters or 42 U.S. gallons at launch) and dinitrogen tetroxide as oxidizer (79.5 liters or 21.0 U.S. gallons at launch).[86]
Comparison with other telescopes
The desire for a large infrared space telescope traces back decades. In the United States, the Space Infrared Telescope Facility (SIRTF, later called the Spitzer Space Telescope) was planned while the Space Shuttle was in development, and the potential for infrared astronomy was acknowledged at that time.[87] Compared to ground telescopes, space observatories were free from atmospheric absorption of infrared light. Space observatories opened up a whole "new sky" for astronomers.[87]
The tenuous atmosphere above the 400 km nominal flight altitude has no measurable absorption so that detectors operating at all wavelengths from 5 μm to 1000 μm can achieve high radiometric sensitivity.
— S. G. McCarthy and G. W. Autio, 1978.[87]
However, infrared telescopes have a disadvantage: they need to stay extremely cold, and the longer the wavelength of infrared, the colder they need to be.[52] If not, the background heat of the device itself overwhelms the detectors, making it effectively blind.[52] This can be overcome by careful spacecraft design, in particular by placing the telescope in a dewar with an extremely cold substance, such as liquid helium.[52] This has meant most infrared telescopes have a lifespan limited by their coolant, as short as a few months, maybe a few years at most.[52]
In some cases, it has been possible to maintain a temperature low enough through the design of the spacecraft to enable near-infrared observations without a supply of coolant, such as the extended missions of Spitzer Space Telescope and Wide-field Infrared Survey Explorer. Another example is Hubble's Near Infrared Camera and Multi-Object Spectrometer (NICMOS) instrument, which started out using a block of nitrogen ice that depleted after a couple of years, but was then converted to a cryocooler that worked continuously. The James Webb Space Telescope is designed to cool itself without a dewar, using a combination of sunshields and radiators, with the mid-infrared instrument using an additional cryocooler.[88]
Name | Year | Wavelength (μm) |
Aperture (m) |
Cooling |
---|---|---|---|---|
Spacelab Infrared Telescope (IRT) | 1985 | 1.7–118 | 0.15 | Helium |
Infrared Space Observatory (ISO)[90] | 1995 | 2.5–240 | 0.60 | Helium |
Hubble Space Telescope Imaging Spectrograph (STIS) | 1997 | 0.115–1.03 | 2.4 | Passive |
Hubble Near Infrared Camera and Multi-Object Spectrometer (NICMOS) | 1997 | 0.8–2.4 | 2.4 | Nitrogen, later cryocooler |
Spitzer Space Telescope | 2003 | 3–180 | 0.85 | Helium |
Hubble Wide Field Camera 3 (WFC3) | 2009 | 0.2–1.7 | 2.4 | Passive, and thermo-electric[91] |
Herschel Space Observatory | 2009 | 55–672 | 3.5 | Helium |
James Webb Space Telescope | 2021 | 0.6–28.5 | 6.5 | Passive, and cryocooler (MIRI) |
JWST's delays and cost increases can be compared to the Hubble Space Telescope.[92] When Hubble formally started in 1972, it had an estimated development cost of US$300 million (or about US$1 billion in 2006 constant dollars),[92] but by the time it was sent into orbit in 1990, the cost was about four times that.[92] In addition, new instruments and servicing missions increased the cost to at least US$9 billion by 2006.[92]
Of the other NASA observatories that were proposed around the same time, most have already been canceled or put on hold, including Terrestrial Planet Finder (2011), Space Interferometry Mission (2010), International X-ray Observatory (2011), MAXIM (Microarcsecond X-ray Imaging Mission), SAFIR (Single Aperture Far-Infrared Observatory), SUVO (Space Ultraviolet-Visible Observatory), and SPECS (Submillimeter Probe of the Evolution of Cosmic Structure).[citation needed]
History
Background (development to 2003)
Year | Events |
---|---|
1996 | Next Generation Space Telescope project started (8 m) |
2002 | named James Webb Space Telescope, Chg to 6 m |
2003 | TRW contract awarded to build |
2004 | NEXUS cancelled[93] |
2007 | ESA/NASA MOU |
2010 | MCDR passed |
2011 | Proposed cancel |
2016 | Final assembly completed |
2021 | Launch |
Discussions of a Hubble follow-on started in the 1980s, but serious planning began in the early 1990s.[94] The Hi-Z telescope concept was developed between 1989 and 1994:[95] a fully baffled[Note 1] 4 m (13 ft) aperture infrared telescope that would recede to an orbit at 3 Astronomical unit (AU).[96] This distant orbit would have benefited from reduced light noise from zodiacal dust.[96] Other early plans called for a NEXUS precursor telescope mission.[97][98]
Correcting the disappointing performance of the Hubble Space Telescope in its first years played a significant role in the birth of the JWST. In 1993, NASA readied STS-61, the Space Shuttle mission that would carry a replacement for HST's camera and a retrofit for its imaging spectrograph to compensate for the spherical aberration in its primary mirror. While the astronomical community eagerly awaited this mission, NASA cautioned that this extraordinary advance in working in space carried significant risk and that its successful completion was in no way guaranteed.[citation needed]
Consequently, the "HST & Beyond Committee", was formed in 1995 to evaluate the effectiveness of the HST repair mission and to explore ideas for future space telescopes that would be needed if the repair mission fell short.[99] It had the good fortune to see the success of the Space Shuttle Servicing Mission 1 in December 1993 and the unprecedented public response to the stunning images that the HST delivered.[citation needed]
Emboldened by HST's success, and recognizing innovative work in Europe for future missions[100][101] its 1996 report explored the concept of a larger and much colder, infrared-sensitive telescope that could reach back in cosmic time to the birth of the first galaxies. This high-priority science goal was beyond the HST's capability because, as a warm telescope, it is blinded by infrared emission from its own optical system. In addition to recommendations to extend the HST mission to 2005 and to develop technologies for finding planets around other stars, NASA embraced the chief recommendation of HST & Beyond[102] for a large, cold space telescope (radiatively cooled to hundreds of degrees below 0 °C), and began the planning process for the future JWST.
Beginning in the 1960s, and at the beginning of each decade since, the National Academies had organized the community of U.S. astronomers to think creatively about astronomical instruments and research for the subsequent decade, and to reach consensus on goals and priorities. A faithful supporter of these 'Decadal Surveys of Astronomy and Astrophysics', NASA has also been extraordinarily successful in developing programs and tools to accomplish Survey recommendations. So, even with the substantial support and excitement in the mid-1990s for NASA's beginning to work on a successor to the HST, the astronomical community regarded as essential a high prioritization by the 2000 Decadal Survey.
Preparation for the Survey included further development of the scientific program for what became known as the "Next Generation Space Telescope",[103] and advancements in relevant technologies by NASA. As it matured, studying the birth of galaxies in the young universe, and searching for planets around other stars – the prime goals coalesced as "Origins" by HST & Beyond became prominent.
Late in the 1990s NASA created the 'Origins Subcommittee' to guide this effort and the 'Beyond Einstein Subcommittee' to oversee missions where the universe is a laboratory for fundamental astrophysics, for example, black holes and supernovae. As hoped, the NGST received the highest ranking in the 2000 Decadal Survey of Astronomy & Astrophysics,[104] which allowed the project to proceed with the full endorsement of a community consensus.
An administrator at NASA, Dan Goldin, coined the phrase “faster, better, cheaper”, and opted for the next big paradigm shift for astronomy, namely, breaking the barrier of a single mirror. That meant going from “eliminate moving parts” to “learn to live with moving parts” (i.e. segmented optics). With the goal to reduce mass density a tenfold, silicon carbide with a very thin layer of glass on top was first looked at, but beryllium has been selected at the end.[94]
"Faster, better, cheaper" mid-1990s era produced the NGST concept, with an 8 m (26 ft) aperture to be flown to L2, roughly estimated to cost US$500 million.[22][22] In 1997, NASA worked with the Goddard Space Flight Center,[105] Ball Aerospace & Technologies,[106] and TRW[107] to conduct technical requirement and cost studies of the three different concepts, and in 1999 selected Lockheed Martin[108] and TRW for preliminary concept studies.[109] Launch was at that time planned for 2007, but the launch date was pushed back many times (see table further down).
In 2002, the project was renamed after NASA's second administrator (1961–1968) James E. Webb (1906–1992). Webb led the agency during the Apollo program and established scientific research as a core NASA activity.[110]
In 2003, NASA awarded TRW the US$824.8 million prime contract for JWST. The design called for a de-scoped 6.1 m (20 ft) primary mirror and a launch date of 2010.[111] Later that year, TRW was acquired by Northrop Grumman in a hostile bid and became Northrop Grumman Space Technology.[109]
JWST is a project of NASA, with international collaboration from the European Space Agency (ESA) and the Canadian Space Agency (CSA) who formally joined in 2004 and 2007 respectively.
Development - (re) planning - 2005
Development was managed by NASA's Goddard Space Flight Center in Greenbelt, Maryland, with John C. Mather as its project scientist. The primary contractor was Northrop Grumman Aerospace Systems, responsible for developing and building the spacecraft element, which included the satellite bus, sunshield, Deployable Tower Assembly (DTA) which connects the Optical Telescope Element to the spacecraft bus, and the Mid Boom Assembly (MBA) which helps to deploy the large sunshields on orbit,[112] while Ball Aerospace & Technologies has been subcontracted to develop and build the OTE itself, and the Integrated Science Instrument Module (ISIM).[71]
Cost growth revealed in spring 2005 led to an August 2005 re-planning.[23] The primary technical outcomes of the re-planning were significant changes in the integration and test plans, a 22-month launch delay (from 2011 to 2013), and elimination of system-level testing for observatory modes at wavelength shorter than 1.7 μm. Other major features of the observatory were unchanged. Following the re-planning, the project was independently reviewed in April 2006.
In the 2005 re-plan, the life-cycle cost of the project was estimated at US$4.5 billion. This comprised approximately US$3.5 billion for design, development, launch and commissioning, and approximately US$1.0 billion for ten years of operations.[23] ESA agreed in 2004 to contributing about €300 million, including the launch.[113] The Canadian Space Agency pledged $39 million Canadian in 2007[114] and in 2012 delivered its contributions in equipment to point the telescope and detect atmospheric conditions on distant planets.[115]
Construction (detailed design - from 2007)
In January 2007, nine of the ten technology development items in the project successfully passed a Non-Advocate Review.[116] These technologies were deemed sufficiently mature to retire significant risks in the project. The remaining technology development item (the MIRI cryocooler) completed its technology maturation milestone in April 2007. This technology review represented the beginning step in the process that ultimately moved the project into its detailed design phase (Phase C). By May 2007, costs were still on target.[117] In March 2008, the project successfully completed its Preliminary Design Review (PDR). In April 2008, the project passed the Non-Advocate Review. Other passed reviews include the Integrated Science Instrument Module review in March 2009, the Optical Telescope Element review completed in October 2009, and the Sunshield review completed in January 2010.[118]
In April 2010, the telescope passed the technical portion of its Mission Critical Design Review (MCDR). Passing the MCDR signified the integrated observatory can meet all science and engineering requirements for its mission.[119] The MCDR encompassed all previous design reviews. The project schedule underwent review during the months following the MCDR, in a process called the Independent Comprehensive Review Panel, which led to a re-plan of the mission aiming for a 2015 launch, but as late as 2018. By 2010, cost over-runs were impacting other projects, though JWST itself remained on schedule.[120]
By 2011, the JWST project was in the final design and fabrication phase (Phase C). As is typical for a complex design that cannot be changed once launched, there are detailed reviews of every portion of design, construction, and proposed operation. New technological frontiers were pioneered by the project, and it passed its design reviews. In the 1990s it was unknown if a telescope so large and of such low mass was possible.[121]
Assembly of the hexagonal segments of the primary mirror, which was done via robotic arm, began in November 2015 and was completed February 3, 2016. The secondary mirror was installed on 3 March 2016.[122][123] Final construction of the Webb telescope was completed in November 2016, after which extensive testing procedures began.[124]
In March 2018, NASA delayed JWST's launch an additional year to May 2020 after the telescope's sunshield ripped during a practice deployment and the sunshield's cables did not sufficiently tighten. In June 2018, NASA delayed the launch by an additional 10 months to March 2021, based on the assessment of the independent review board convened after the failed March 2018 test deployment.[125] The review identified that JWST launch and deployment had 344 potential single-point failures - tasks that had no alternative or means of recovery if unsuccessful, and therefore had to succeed for the telescope to work.[126] In August 2019, the mechanical integration of the telescope was completed, something that was scheduled to be done 12 years before in 2007.[127]
After construction was completed, JWST underwent final tests at a Northrop Grumman factory in Redondo Beach, California.[128] A ship carrying the telescope left California on 26 September 2021, passed through the Panama Canal, and arrived in French Guiana on 12 October 2021.[129]
Cost and schedule issues
NASA's lifetime cost for the project is expected to be US$9.7 billion, of which US$8.8 billion was spent on spacecraft design and development and US$861 million is planned to support five years of mission operations.[130] Representatives from ESA and CSA stated their project contributions amount to approximately €700 million and CA$200 million, respectively.[131]
JWST has a history of major cost overruns and delays which have resulted in part from outside factors such as delays in deciding on a launch vehicle and adding extra funding for contingencies. By 2006, US$1 billion had been spent on developing JWST, with the budget at about US$4.5 billion at that time. A 2006 article in the journal Nature noted a study in 1984 by the Space Science Board, which estimated that a next generation infrared observatory would cost US$4 billion (about US$7 billion in 2006 dollars).[92]
Year | Planned launch |
Budget plan (billion USD) |
---|---|---|
1997 | 2007[121] | 0.5[121] |
1998 | 2007[132] | 1[92] |
1999 | 2007 to 2008[133] | 1[92] |
2000 | 2009[76] | 1.8[92] |
2002 | 2010[134] | 2.5[92] |
2003 | 2011[135] | 2.5[92] |
2005 | 2013 | 3[136] |
2006 | 2014 | 4.5[137] |
2008: Preliminary Design Review | ||
2008 | 2014 | 5.1[138] |
2010: Critical Design Review | ||
2010 | 2015 to 2016 | 6.5[139] |
2011 | 2018 | 8.7[140] |
2013 | 2018 | 8.8[141] |
2017 | 2019[142] | 8.8 |
2018 | 2020[143] | ≥8.8 |
2019 | March 2021[144] | 9.66 |
2021 | Dec 2021[145] | 9.70 |
The telescope was originally estimated to cost US$1.6 billion,[146] but the cost estimate grew throughout the early development and had reached about US$5 billion by the time the mission was formally confirmed for construction start in 2008. In summer 2010, the mission passed its Critical Design Review (CDR) with excellent grades on all technical matters, but schedule and cost slips at that time prompted Maryland U.S. Senator Barbara Mikulski to call for an independent review of the project. The Independent Comprehensive Review Panel (ICRP) chaired by J. Casani (JPL) found that the earliest possible launch date was in late 2015 at an extra cost of US$1.5 billion (for a total of US$6.5 billion). They also pointed out that this would have required extra funding in FY2011 and FY2012 and that any later launch date would lead to a higher total cost.[139]
On 6 July 2011, the United States House of Representatives' appropriations committee on Commerce, Justice, and Science moved to cancel the James Webb project by proposing an FY2012 budget that removed US$1.9 billion from NASA's overall budget, of which roughly one quarter was for JWST.[147][148][149][150] US$3 billion had been spent and 75% of its hardware was in production.[151] This budget proposal was approved by subcommittee vote the following day. The committee charged that the project was "billions of dollars over budget and plagued by poor management."[147] In response, the American Astronomical Society issued a statement in support of JWST,[152] as did Maryland US Senator Barbara Mikulski.[153] A number of editorials supporting JWST appeared in the international press during 2011 as well.[147][154][155] In November 2011, Congress reversed plans to cancel JWST and instead capped additional funding to complete the project at US$8 billion.[156]
Some scientists expressed concerns about growing costs and schedule delays for the Webb telescope, which competed for scant astronomy budgets and thus threatened funding for other space science programs.[157][141] Because the runaway budget diverted funding from other research, a 2010 Nature article described JWST as "the telescope that ate astronomy".[158]
A review of NASA budget records and status reports noted that JWST was plagued by many of the same problems that have affected other major NASA projects. Repairs and additional testing included underestimates of the telescope's cost that failed to budget for expected technical glitches, and missed budget projections, thus extending the schedule and increasing costs further.[141][146][159]
On 27 March 2018, NASA announced that JWST's launch would be pushed back to May 2020 or later, admitting that the project's costs might exceed US$8.8 billion.[143] NASA committed to releasing a revised cost estimate after a new launch window was determined with the European Space Agency (ESA).[160][161][162]
In February 2019, despite expressing criticism over cost growth, Congress increased the mission's cost cap by US$800 million.[163]
Partnership
NASA, ESA and CSA have collaborated on the telescope since 1996. ESA's participation in construction and launch was approved by its members in 2003 and an agreement was signed between ESA and NASA in 2007. In exchange for full partnership, representation and access to the observatory for its astronomers, ESA is providing the NIRSpec instrument, the Optical Bench Assembly of the MIRI instrument, an Ariane 5 ECA launcher, and manpower to support operations.[113][164] The CSA will provide the Fine Guidance Sensor and the Near-Infrared Imager Slitless Spectrograph plus manpower to support operations.[165]
Several thousand scientists, engineers, and technicians spanning 15 countries have contributed to the build, test and integration of the JWST.[166] A total of 258 companies, government agencies, and academic institutions are participating in the pre-launch project; 142 from the United States, 104 from 12 European countries, and 12 from Canada.[166] Other countries as NASA partners, such as Australia, have or will be involved in post-launch operation.[167]
- Participating countries
Public displays and outreach
A large telescope model has been on display at various places since 2005: in the United States at Seattle, Washington; Colorado Springs, Colorado; Greenbelt, Maryland; Rochester, New York; New York City; and Orlando, Florida; and elsewhere at Paris, France; Dublin, Ireland; Montreal, Canada; Hatfield, United Kingdom; and Munich, Germany. The model was built by the main contractor, Northrop Grumman Aerospace Systems.[168]
In May 2007, a full-scale model of the telescope was assembled for display at the Smithsonian Institution's National Air and Space Museum on the National Mall, Washington, D.C. The model was intended to give the viewing public a better understanding of the size, scale and complexity of the satellite, as well as pique the interest of viewers in science and astronomy in general. The model is significantly different from the telescope, as the model must withstand gravity and weather, so is constructed mainly of aluminum and steel measuring approximately 24 m × 12 m × 12 m (79 ft × 39 ft × 39 ft) and weighs 5,500 kg (12,100 lb).[169]
The model was on display in New York City's Battery Park during the 2010 World Science Festival, where it served as the backdrop for a panel discussion featuring Nobel Prize laureate John C. Mather, astronaut John M. Grunsfeld and astronomer Heidi Hammel. In March 2013, the model was on display in Austin for SXSW 2013.[170][171] Amber Straughn, the deputy project scientist for science communications, has been a spokesperson for the project at many SXSW events from 2013 onwards in addition to Comic Con, TEDx, and other public venues.[172]
The public was able to follow the progress of the launch and deployment in real-time on NASA's Where is Webb? web site.
Controversy over name
In March 2021, an article in Scientific American urged NASA to reconsider the name of the telescope, based on Webb's alleged complicity during the Lavender Scare persecution of LGBTQ employees during the Harry S. Truman administration.[173] In September 2021, NASA announced it had declined to rename the telescope.[174] Former administrator Sean O'Keefe, who made the decision to name the telescope after administrator Webb, stated that to suggest Webb should "be held accountable for that activity when there's no evidence to even hint [that he participated in it] is an injustice."[175][176][177]
Mission - goals
The James Webb Space Telescope has four key goals:
- to search for light from the first stars and galaxies that formed in the universe after the Big Bang
- to study galaxy formation and evolution
- to understand star formation and planet formation
- to study planetary systems and the origins of life[178]
These goals can be accomplished more effectively by observation in near-infrared light rather than light in the visible part of the spectrum. For this reason, JWST's instruments will not measure visible or ultraviolet light like the Hubble Telescope, but will have a much greater capacity to perform infrared astronomy. JWST will be sensitive to a range of wavelengths from 0.6 to 28 μm (corresponding respectively to orange light and deep infrared radiation at about 100 K or −173 °C).
JWST may be used to gather information on the dimming light of star KIC 8462852, which was discovered in 2015, and has some abnormal light-curve properties.[179]
Orbit - design
JWST will orbit the Sun near the second Lagrange point (L2) of the Sun-Earth system, which is 1,500,000 km (930,000 mi) farther from the Sun than the Earth's orbit, and about four times farther than the moon's orbit. Normally an object circling the Sun farther out than Earth would take longer than one year to complete its orbit. But near the L2 point, the combined gravitational pull of the Earth and the Sun allow a spacecraft to orbit the Sun in the same time that it takes the Earth. Staying close to Earth allows data rates to be much faster for a given size of antenna.
The telescope will circle about the Sun-Earth L2 point in a halo orbit, which will be inclined with respect to the ecliptic, have a radius varying between about 250,000 km (160,000 mi) and 832,000 km (517,000 mi), and take about half a year to complete.[53] Since L2 is just an equilibrium point with no gravitational pull, a halo orbit is not an orbit in the usual sense: the spacecraft is actually in orbit around the Sun, and the halo orbit can be thought of as controlled drifting to remain in the vicinity of the L2 point.[180] This requires some station-keeping: around 2.5 m/s per year[181] from the total ∆v budget of 93 m/s.[182] Two sets of thrusters constitute the observatory's propulsion system.[183] Because the thrusters are located solely on the Sun-facing side of the observatory, all station-keeping operations are designed to slightly undershoot the required amount of thrust in order to avoid pushing the JWST beyond the semi-stable L2 point, a situation which would be unrecoverable. Randy Kimble, the Integration and Test Project Scientist for the James Webb Space Telescope, compared the precise station-keeping of the JWST to "Sisyphus [...] rolling this rock up the gentle slope near the top of the hill – we never want it to roll over the crest and get away from him".[184]
Infrared astronomy
JWST is the formal successor to the Hubble Space Telescope (HST), and since its primary emphasis is on infrared astronomy, it is also a successor to the Spitzer Space Telescope. JWST will far surpass both those telescopes, being able to see many more and much older stars and galaxies.[185] Observing in the infrared spectrum is a key technique for achieving this, because of cosmological redshift, and because it better penetrates obscuring dust and gas. This allows observation of dimmer, cooler objects. Since water vapor and carbon dioxide in the Earth's atmosphere strongly absorbs most infrared, ground-based infrared astronomy is limited to narrow wavelength ranges where the atmosphere absorbs less strongly. Additionally, the atmosphere itself radiates in the infrared spectrum, often overwhelming light from the object being observed. This makes a space telescope preferable for infrared observation.[186]
The more distant an object is, the younger it appears; its light has taken longer to reach human observers. Because the universe is expanding, as the light travels it becomes red-shifted, and objects at extreme distances are therefore easier to see if viewed in the infrared.[187] JWST's infrared capabilities are expected to let it see back in time to the first galaxies forming just a few hundred million years after the Big Bang.[188]
Infrared radiation can pass more freely through regions of cosmic dust that scatter visible light. Observations in infrared allow the study of objects and regions of space which would be obscured by gas and dust in the visible spectrum,[187] such as the molecular clouds where stars are born, the circumstellar disks that give rise to planets, and the cores of active galaxies.[187]
Relatively cool objects (temperatures less than several thousand degrees) emit their radiation primarily in the infrared, as described by Planck's law. As a result, most objects that are cooler than stars are better studied in the infrared.[187] This includes the clouds of the interstellar medium, brown dwarfs, planets both in our own and other solar systems, comets, and Kuiper belt objects that will be observed with the Mid-Infrared Instrument (MIRI).[76][188]
Some of the missions in infrared astronomy that impacted JWST development were Spitzer and the Wilkinson Microwave Anisotropy Probe (WMAP).[189] Spitzer showed the importance of mid-infrared, which is helpful for tasks such as observing dust disks around stars.[189] Also, the WMAP probe showed the universe was "lit up" at redshift 17, further underscoring the importance of the mid-infrared.[189] Both these missions were launched in the early 2000s, in time to influence JWST development.[189]
Ground support and operations
The Space Telescope Science Institute (STScI), in Baltimore, Maryland, on the Homewood Campus of Johns Hopkins University, was selected as the Science and Operations Center (S&OC) for JWST with an initial budget of US$162.2 million intended to support operations through the first year after launch.[190] In this capacity, STScI will be responsible for the scientific operation of the telescope and delivery of data products to the astronomical community. Data will be transmitted from JWST to the ground via the NASA Deep Space Network, processed and calibrated at STScI, and then distributed online to astronomers worldwide. Similar to how Hubble is operated, anyone, anywhere in the world, will be allowed to submit proposals for observations. Each year several committees of astronomers will peer review the submitted proposals to select the projects to observe in the coming year. The authors of the chosen proposals will typically have one year of private access to the new observations, after which the data will become publicly available for download by anyone from the online archive at STScI.
The bandwidth and digital throughput of the satellite is designed to operate at 458 gigabits of data per day for the length of the mission (equivalent to a sustained rate of 5.42 megabits per second (Mbps)).[66] Most of the data processing on the telescope is done by conventional single-board computers.[191] The conversion of the analog science data to digital form is performed by the custom-built SIDECAR ASIC (System for Image Digitization, Enhancement, Control And Retrieval Application Specific Integrated Circuit). NASA stated that the SIDECAR ASIC will include all the functions of a 9.1 kg (20 lb) instrument box in a 3 cm (1.2 in) package and consume only 11 milliwatts of power.[192] Since this conversion must be done close to the detectors, on the cool side of the telescope, the low power use of this IC will be crucial for maintaining the low temperature required for optimal operation of JWST.[192]
Mission progress - from launch onwards
Launch and mission length
Scientists and engineers who worked on the project described their feelings of anticipation and anxiety about the launch of the exhaustively tested[31][32] nearly $10 billion instrument, commenting that it would be "an exciting moment" and they would feel "terrified the entire time".[29][30] The launch (designated Ariane flight VA256) took place as scheduled at 12:20 UTC on 25 December 2021 on an Ariane 5 rocket that lifted off from the Guiana Space Centre in French Guiana.[34][33] Upon successful launch, NASA administrator Bill Nelson called it "a great day for planet Earth".[193] The telescope was confirmed to be receiving power, starting a two-week deployment phase of its parts[194] and traveling to its target destination.[38][39][40] The observatory was attached to the Ariane 5 via a launch vehicle adapter ring which could be used by a future spacecraft to grapple the observatory to attempt to fix gross deployment problems. However, the telescope itself is not serviceable, and astronauts would not be able to perform tasks such as swapping instruments, as with the Hubble Telescope.[68] The telescope was released from the upper stage 27 minutes 7 seconds after launch, beginning a 30-day adjustment to place the telescope in a halo orbit around the L2 Lagrange point.
The telescope was launched with slightly less speed than needed to reach its final orbit, and will also slow down as it travels away from Earth, in order to reach L2 with only the velocity needed to enter its orbit there. The flight includes three planned course corrections to adjust its speed and direction. This is because the observatory can recover from underthrust (going too slowly), but could not recover from overthrust (going too fast) - to protect highly temperature-sensitive instruments, the sunshield must remain between telescope and Sun, so the spacecraft cannot turn around or use its thrusters to slow down.[195]
The telescope's nominal mission time is five years, with a goal of ten years.[196] The planned five-year science mission begins after a six-month commissioning phase.[197] An L2 orbit is unstable, so JWST needs to use propellant to maintain its halo orbit around L2 (known as station-keeping) to prevent the telescope from drifting away from its orbital position.[198] It was designed to carry enough fuel for 10 years,[197] but the precision of the Ariane 5 launch and the first midcourse correction were credited with saving enough onboard fuel that JWST may be able to maintain its orbit for around 20 years instead.[199][200][201]
-
Ariane 5 and JWST at the ELA-3 launch pad
-
Ariane 5 containing JWST moments after lift-off
-
JWST as seen from the ESC-D Cryotechnic upper stage shortly after separation, approximately 29 minutes after launch. Part of the Earth with the Gulf of Aden can be seen in the background.[202]
Transit and structural deployment
Starting 31 minutes after launch, and continuing for about 13 days, JWST began the process of deploying its solar array, antenna, sunshield, and mirrors.[203] Nearly all deployment actions are commanded by the Space Telescope Science Institute in Baltimore, except for two early automatic steps, solar panel unfolding and communication antenna deployment.[204][205] The mission was designed to give ground controllers flexibility to change or modify the deployment sequence in case of problems.[206]
The electricity-generating solar panel deployed on the day of launch, one and a half minutes after the telescope separated from the Ariane rocket second stage;[199][206] this took place slightly sooner than expected because launch rotation was much closer to ideal than deployment plans had envisaged.[207] The separation and solar panel extension were both visible in a live feed from a camera on the rocket.[208]
After deployment of the solar arrays, power output was reduced due to a factory pre-set duty cycle in the array regulator module which was set prior to launch. Power usage was greater than that supplied by the solar arrays and this resulted in increased drawdown of the telescope's batteries and higher than expected voltage. To ensure power delivery would be sufficient for spacecraft and science operations, the solar panels were reset and duty cycles were optimized to account for the real world conditions observed including array temperatures.[209] Higher than desired temperatures were observed in some of the shade deployment motors. While the motors remained well within their operational tolerances, to ensure greater margins the spacecraft's attitude was adjusted to aid the motors in reaching their desired temperatures and the motors were rebalanced. This was done based on results from simulator testing.[209] The majority of forecast models of vehicle behavior and conditions matched the operational evolution[jargon] in space.[209]
At 7:50 p.m. EST on December 25, about 12 hours after launch, the telescope's pair of primary rockets began firing for 65 minutes to make the first of three planned mid-course corrections.[210] On day two, the high gain communication antenna deployed automatically.[206]
On December 27, at 60 hours after launch, Webb's rockets fired for nine minutes and 27 seconds to make the second of three mid-course corrections for the telescope to arrive at its L2 destination.[211] On December 28, three days after launch, mission controllers began the multi-day deployment of Webb's all-important sunshield. Controllers sent commands that successfully lowered the forward and aft pallet structures, which contain the sunshield. This deployment precedes the actual unfolding and extension of the delicate shield membranes, which are pulled out of the pallets by telescoping beams in a subsequent step.[212][213]
On December 29, controllers successfully extended the Deployable Tower Assembly, a pipe-like column, which moved apart the two main segments of the observatory, the telescope with its mirrors and scientific instruments, and the "bus" holding electronics and propulsion. The assembly lengthened 48 in (1,200 mm) in a process that lasted six and a half hours, including many preparatory commands. Deployment created the needed distance between the JWST segments to allow extreme cooling of the telescope and room for the sunshield to unfold.[214][215] On December 30, controllers successfully completed two more steps in unpacking the observatory. First, commands deployed the aft "momentum flap", a device that provides balance against solar pressure on the sunshield, saving fuel by reducing the need for thruster firing to maintain Webb's orientation.[216] Next, mission control released and rolled up covers that protect the sunshield, exposing it to space for the first time.[217][64]
On December 31, the ground team extended the two telescoping "mid booms" from the left and right sides of the observatory, pulling the five sunshield membranes out of their folded stowage in the fore and aft pallets, which were lowered three days earlier.[218] Deployment of the left side boom (in relation to pointing direction of the main mirror) was delayed when mission control did not initially receive confirmation that the sunshield cover had fully rolled up. After looking at extra data for confirmation, the team proceeded to extend the booms.[219] The left side deployed in 3 hours and 19 minutes; the right side took 3 hours and 42 minutes.[219][218] With that step, Webb's sunshield resembled its complete, kite-shaped form and extended to its full 47-foot width. Commands to separate and tension the membranes were to follow[218] and were expected to take several days.[209]
After resting on New Year's Day, the ground team delayed sunshield tensioning one day to allow time to optimize the observatory's array of solar panels and to adjust the orientation of the observatory slightly to cool the slightly hotter-than-expected sunshield deployment motors.[220] Tensioning of layer one, closest to the Sun and largest of the five in the sunshield, began on January 3, 2022, and was completed at 3:48 p.m. EST.[221] Tensioning of the second and third layers began at 4:09 p.m. EST and took two hours and 25 minutes.[222] On January 4, controllers successfully tensioned the last two layers, four and five, completing the task at 11:59 a.m. EST.[223]
On January 5, 2022, mission control successfully deployed the telescope's secondary mirror, which locked itself into place to a tolerance of about one and a half millimeters.[224]
The last step of structural deployment was to unfold the wings of the primary mirror. Each panel consists of three primary mirror segments and had to be folded to allow the space telescope to be installed in the fairing of the Ariane rocket for the launch of the telescope. On January 7, 2022, NASA deployed and locked in place the port-side wing,[225] and on January 8, the starboard-side mirror wing. This successfully completed the structural deployment of the observatory.[226][227][228]
Nearly a month after launch, another trajectory correction will be initiated, for JWST to enter its planned halo orbit around the Sun-Earth L2 point.[229]
-
Planned structural deployment sequence
-
Planned structural deployment timeline[68]
-
Animation of JWST's halo orbit
Commissioning and testing
On January 12, 2022, while still in transit, mirror alignment began. The primary mirror segments are moved away from their protective launch positions. This will take about 10 - 12 days, because the 126 actuator motors are designed to fine-tune the mirror positions at microscopic accuracy (10 nanometer increments) and must each move over 1.2 million increments (12.5mm) during initial alignment.[230][231] Also, to reduce risk and complexity, and to minimise heat production near the cooling mirrors, only one actuator is moved at a time and the actuators only operate for short periods at a time, limiting total speed to about 1mm per day.[230][231] After being freed from launch protection, the mirror segments will be fine tuned and aligned to work as a single mirror, a process expected to take around 3 of the 5 months allowed for commissioning and testing.[231]
Allocation of observation time
JWST observing time is allocated through a General Observers (GO) program, a Guaranteed Time Observations (GTO) program, and a Director's Discretionary Early Release Science (DD-ERS) program.[232] The GTO program provides guaranteed observing time for scientists who developed hardware and software components for the observatory. The GO program provides all astronomers the opportunity to apply for observing time and will represent the bulk of the observing time. GO programs are selected through peer review by a Time Allocation Committee (TAC), similar to the proposal review process used for the Hubble Space Telescope.
Early Release Science program
In November 2017, the Space Telescope Science Institute announced the selection of 13 Director's Discretionary Early Release Science (DD-ERS) programs, chosen through a competitive proposal process.[233][234] The observations for these programs will be obtained during the first five months of JWST science operations after the end of the commissioning period. A total of 460 hours of observing time was awarded to these 13 programs, which span science topics including the Solar System, exoplanets, stars and star formation, nearby and distant galaxies, gravitational lenses, and quasars.
General Observer Program
For GO Cycle 1, 6000 hours of observation time were available to allocate, and 1173 proposals were submitted requesting a total of 24,500 hours of observation time.[235] Selection of Cycle 1 GO programs was announced on 30 March 2021, with 266 programs approved. These include 13 large programs and treasury programs producing data for public access.[236]
See also
- Attitude control
- James Webb Space Telescope timeline
- List of largest infrared telescopes
- List of largest optical reflecting telescopes
- List of space telescopes
- Nancy Grace Roman Space Telescope, planned launch no later than 2027
- New Worlds Mission (proposed occulter for the JWST)
- Physical cosmology
- Satellite bus
- Solar panels on spacecraft
- Spacecraft design
- Spacecraft thermal control
Explanatory notes
- ^ "Baffled", in this context, means enclosed in a tube in a similar manner to a conventional optical telescope, which helps to stop stray light entering the telescope from the side. For an actual example, see the following link: Freniere, E.R. (1981). "First-order design of optical baffles". Society of Photo-Optical Instrumentation Engineers (SPIE) Conference Series, First-order design of optical baffles. Radiation Scattering in Optical Systems. Vol. 257. pp. 19–28. Bibcode:1981SPIE..257...19F. doi:10.1117/12.959598.
References
- ^ a b "NASA JWST "Who are the partners in the Webb project?"". NASA. Retrieved 18 November 2011. This article incorporates text from this source, which is in the public domain.
- ^ Kelso, Thomas S. (25 December 2021). "JWST". Celestrak. Celestrak. Retrieved 26 December 2021.
- ^ "NASA Says Webb's Excess Fuel Likely to Extend its Lifetime Expectations – James Webb Space Telescope". blogs.nasa.gov.
- ^ "FAQ Full General Public Webb Telescope/NASA". jwst.nasa.gov.
- ^ Clark, Stephen [@StephenClark1] (23 December 2021). "The exact launch mass of the James Webb Space Telescope: 6161.4 kilograms. That figure includes 167.5 kg of hydrazine and 132.5 kg of dinitrogen tetroxide for the propulsion system" (Tweet). Retrieved 23 December 2021 – via Twitter.
- ^ a b "JWST Orbit". JWST User Documentation. Space Telescope Science Institute. Retrieved 25 December 2021.
- ^ "JWST Telescope". James Webb Space Telescope User Documentation. Space Telescope Science Institute. 23 December 2019. Retrieved 11 June 2020. This article incorporates text from this source, which is in the public domain.
- ^ Meet the team: Partners and Contributors - official NASA website of James Webb Space Telescope
- ^ Witze, Alexndra (23 July 2021). "NASA investigates renaming James Webb telescope after anti-LGBT+ claims. Some astronomers argue the flagship observatory – successor to the Hubble Space Telescope – will memorialize discrimination. Others are waiting for more evidence". Nature. 596 (7870): 15–16. doi:10.1038/d41586-021-02010-x. PMID 34302150. S2CID 236212498. Retrieved 23 July 2021.
- ^ "ESA JWST Timeline". Archived from the original on 21 August 2003. Retrieved 13 January 2012. This article incorporates text from this source, which is in the public domain.
- ^ During, John. "The James Webb Space Telescope". NASA. Retrieved 31 December 2011. This article incorporates text from this source, which is in the public domain.
- ^ "About the James Webb Space Telescope". Retrieved 13 January 2012. This article incorporates text from this source, which is in the public domain.
- ^ "How does the Webb Contrast with Hubble?". NASA. Archived from the original on 3 December 2016. Retrieved 4 December 2016. This article incorporates text from this source, which is in the public domain.
- ^ a b c d "A Deeper Sky | by Brian Koberlein". briankoberlein.com.
- ^ "Mirrors Webb/NASA". webb.nasa.gov. Retrieved 30 December 2021.
- ^ "James Webb Space Telescope JWST History: 1989–1994". Space Telescope Science Institute, Baltimore, Maryland. 2017. Archived from the original on 3 February 2014. Retrieved 29 December 2018.
- ^ "Instrumentation of JWST". Space Telescope Science Institute. 29 January 2020. Retrieved 29 January 2020.
- ^ "L2, the second Lagrangian Point". Retrieved 5 December 2021.
- ^ a b c d "The Sunshield". nasa.gov. NASA. Retrieved 28 August 2016. This article incorporates text from this source, which is in the public domain.
- ^ "About Webb". NASA. 2019. Retrieved 4 June 2021. This article incorporates text from this source, which is in the public domain.
- ^ "James Webb Space Telescope". Northrop Grumman. 2017. Retrieved 31 January 2017.
- ^ a b c "STSCI JWST History 1996". Stsci.edu. Archived from the original on 3 February 2014. Retrieved 16 January 2012.
- ^ a b c John Mather. "James Webb Space Telescope (JWST)" (PDF). National Academy of Science. Archived from the original (PDF) on 10 November 2008. Retrieved 5 July 2008. This article incorporates text from this source, which is in the public domain.
- ^ Foust, Jeff (20 March 2020). "Coronavirus pauses work on JWST". SpaceNews.
- ^ "James Webb Space Telescope to launch in October 2021". www.esa.int. This article incorporates text from this source, which is in the public domain.
- ^ Overbye, Dennis (16 July 2020). "NASA Delays James Webb Telescope Launch Date, Again – The universe will have to wait a little longer". The New York Times. Retrieved 17 July 2020.
- ^ Foust, Jeff (12 May 2021). "Ariane 5 issue could delay JWST". SpaceNews. Retrieved 13 May 2021.
- ^ "Update on Webb telescope launch". NASA. 14 December 2021. Retrieved 14 December 2021. This article incorporates text from this source, which is in the public domain.
- ^ a b Overbye, Dennis (14 December 2021). "Why the World's Astronomers Are Very, Very Anxious Right Now – The James Webb Space Telescope is endowed with the hopes and trepidations of a generation of astronomers". The New York Times. Retrieved 15 December 2021.
- ^ a b Karlis, Nicole (19 December 2021). "Decades of work are riding on the James Webb Space Telescope – What happens if it fails? – As one of the most expensive space missions in history, there's a lot on the line for launch". salon.com. Retrieved 19 December 2021.
- ^ a b "James Webb Space Telescope observatory is assembled". Space Daily. 29 December 2016. Retrieved 3 February 2017.
- ^ a b Foust, Jeff (23 December 2016). "No damage to JWST after vibration test anomaly". SpaceNews. Retrieved 3 February 2017.
- ^ a b Pinoi, Natasha; Fiser, Alise; Betz, Laura (27 December 2021). "NASA's Webb Telescope Launches to See First Galaxies, Distant Worlds - NASA's James Webb Space Telescope launched at 7:20 a.m. EST Saturday [Dec. 25, 2021] on an Ariane 5 rocket from Europe's Spaceport in French Guiana, South America". NASA. Retrieved 28 December 2021.
- ^ a b "Ariane 5 goes down in history with successful launch of Webb". Arianespace (Press release). 25 December 2021. Retrieved 25 December 2021.
- ^ published, Tereza Pultarova (25 December 2021). "'It's truly Christmas': James Webb Space Telescope's yuletide launch has NASA overjoyed". Space.com.
- ^ Roulette, Joey; Overbye, Dennis (8 January 2022). "The James Webb Space Telescope Finishes Unfolding: How to Watch - While there are no cameras aboard the spacecraft, NASA is providing updates as the telescope deploys its mirrors. Here's what you need to know". The New York Times. Retrieved 8 January 2022.
- ^ Pinol, Natasha; Fisher, Alise; Betz, Laura; Margetta, Robert (8 January 2022). "Release 22-004: NASA's Webb Telescope Reaches Major Milestone as Mirror Unfolds". NASA. Retrieved 9 January 2022.
- ^ a b Achenbach, Joel (25 December 2021). "NASA's James Webb Space Telescope launches in French Guiana – $10 billion successor to Hubble telescope will capture light from first stars and study distant worlds". The Washington Post. Retrieved 25 December 2021.
- ^ a b Staff (25 December 2021). "Live Updates: Webb Telescope Launches on Long-Awaited Journey". The New York Times. Retrieved 25 December 2021.
- ^ a b Overbye, Dennis; Roulette, Joey (25 December 2021). "James Webb Space Telescope Launches on Journey to See the Dawn of Starlight - Astronomers were jubilant as the spacecraft made it off the launchpad, following decades of delays and cost overruns. The Webb is set to offer a new keyhole into the earliest moments of our universe". The New York Times. Retrieved 25 December 2021.
- ^ Mission and Launch Quick Facts - "After reaching its orbit, Webb undergoes science and calibration testing. Then, regular science operations and images will begin to arrive, approximately six months after launch. However, it is normal to also take a series of "first light" images that may arrive slightly earlier."
- ^ NASA JWST Blog: observations expected to be available by summer 2022 ("Rest assured that this summer will sizzle with the hot (nay cold?) observations we will soon be sharing!")
- ^ Overbye, Dennis; Roulette, Joey (8 January 2022). "A Giant Telescope Grows in Space - Everything is going great for the James Webb Space Telescope. So far". The New York Times. Retrieved 9 January 2022.
- ^ Koren, Marina (8 January 2022). "Even NASA Seems Surprised by Its New Space Telescope - The $10 billion mission is working better than anyone could have predicted". The Atlantic. Retrieved 10 January 2022.
- ^ Lallo, Matthew D. (2012). "Experience with the Hubble Space Telescope: 20 years of an archetype". Optical Engineering. 51 (1): 011011–011011–19. arXiv:1203.0002. Bibcode:2012OptEn..51a1011L. doi:10.1117/1.OE.51.1.011011. S2CID 15722152.
- ^ "NASA - The "Not So Heavy Metal Video": James Webb Space Telescope's Beryllium Mirrors". www.nasa.gov.
- ^ a b c "FAQ for Scientists Webb Telescope/NASA". jwst.nasa.gov.
- ^ Shelton, Jim (3 March 2016). "Shattering the cosmic distance record, once again". Yale University. Retrieved 4 March 2016.
- ^ "Hubble breaks cosmic distance record". SpaceTelescope.org. 3 March 2016. heic1604. Retrieved 3 March 2016.
- ^ Oesch, P. A.; Brammer, G.; van Dokkum, P.; et al. (March 2016). "A Remarkably Luminous Galaxy at z=11.1 Measured with Hubble Space Telescope Grism Spectroscopy". The Astrophysical Journal. 819 (2). 129. arXiv:1603.00461. Bibcode:2016ApJ...819..129O. doi:10.3847/0004-637X/819/2/129. S2CID 119262750.
{{cite journal}}
: CS1 maint: unflagged free DOI (link) - ^ Atkinson, Nancy. "Hubble Has Looked Back in Time as Far as It Can And Still Can't Find The First Stars". Universe Today – via ScienceAlert.
- ^ a b c d e "Infrared astronomy from earth orbit". Infrared Processing and Analysis Center, NASA Spitzer Science Center, California Institute of Technology. 2017. Archived from the original on 21 December 2016. This article incorporates text from this source, which is in the public domain.
- ^ a b c "L2 Orbit". Space Telescope Science Institute. Archived from the original on 3 February 2014. Retrieved 28 August 2016.
- ^ Drake, Nadia (24 April 2015). "Hubble Still Wows At 25, But Wait Till You See What's Next". National Geographic.
- ^ "Why is Webb not serviceable like Hubble?". James Webb Space Telescope (FAQ). Retrieved 31 December 2021.
- ^ a b "Relief as NASA's most powerful space telescope finishes risky unfolding". Science. 8 January 2022.
- ^ Smith, Marcia (30 August 2018). "Zurbuchen Taking One Last Look at JWST Servicing Compatiblity". SpacePolicyOnline. Retrieved 31 December 2021.
- ^ Foust, Jeff (2 February 2018). "Scientists, engineers push for servicing and assembly of future space observatories". SpaceNews. Retrieved 31 December 2021.
- ^ Grush, Loren (28 December 2021). "NASA's James Webb Space Telescope is about to transform into its final form". The Verge.
- ^ "The James Webb Space Telescope". nasa.gov. Retrieved 28 August 2016. This article incorporates text from this source, which is in the public domain.
- ^ "Sunshield Coatings Webb/NASA". jwst.nasa.gov. Retrieved 3 May 2020. This article incorporates text from this source, which is in the public domain.
- ^ Clery, Daniel (27 March 2018). "NASA announces more delays for giant space telescope". Science. Retrieved 5 June 2018.
- ^ Morring, Frank Jr. (16 December 2013). "JWST Sunshade Folding, Deployment In Test". Aviation Week & Space Technology. pp. 48–49. ISSN 0005-2175.
- ^ a b Fisher, Alise. "Webb Ready for Sunshield Deployment and Cooldown". James Webb Space Telescope (NASA Blogs). Retrieved 31 December 2021.
- ^ "JWST Wavefront Sensing and Control". Space Telescope Science Institute. Archived from the original on 5 August 2012. Retrieved 9 June 2011.
- ^ a b Mallonee, Laura. "NASA's Biggest Telescope Ever Prepares for a 2021 Launch". 9. Retrieved 4 June 2021.
- ^ "JWST Mirrors". Space Telescope Science Institute. Archived from the original on 5 August 2012. Retrieved 9 June 2011.
- ^ a b c d "JWST". NASA. Retrieved 29 June 2015. This article incorporates text from this source, which is in the public domain.
- ^ "Science Instruments of NASA's James Webb Space Telescope Successfully Installed". NASA. 24 May 2016. Retrieved 2 February 2017. This article incorporates text from this source, which is in the public domain.
- ^ "James Webb Space Telescope Marks Manufacturing Milestone (Press Release)". Space Ref. 23 August 2005. Retrieved 25 December 2021.
- ^ a b "JWST: Integrated Science Instrument Module (ISIM)". NASA. 2017. Retrieved 2 February 2017. This article incorporates text from this source, which is in the public domain.
- ^ "James Webb Space Telescope Near Infrared Camera". STScI. Archived from the original on 21 March 2013. Retrieved 24 October 2013.
- ^ "NIRCam for the James Webb Space Telescope". University of Arizona. Retrieved 24 October 2013.
- ^ a b c "JWST Current Status". STScI. Archived from the original on 15 July 2009. Retrieved 5 July 2008.
- ^ a b c "NIRSpec – the near-infrared spectrograph on JWST". European Space Agency. 22 February 2015. Retrieved 2 February 2017.
- ^ a b c "MIRI spectrometer for NGST". Archived from the original on 27 September 2011.
- ^ a b "JWST: Mid-Infrared Instrument (MIRI)". NASA. 2017. Retrieved 3 February 2017. This article incorporates text from this source, which is in the public domain.
- ^ Banks, Kimberly; Larson, Melora; Aymergen, Cagatay; Zhang, Burt (2008). Angeli, George Z.; Cullum, Martin J. (eds.). "James Webb Space Telescope Mid-Infrared Instrument Cooler systems engineering" (PDF). Proceedings of SPIE. Modeling, Systems Engineering, and Project Management for Astronomy III. 7017: 5. Bibcode:2008SPIE.7017E..0AB. doi:10.1117/12.791925. S2CID 17507846. Retrieved 6 February 2016.
Fig. 1. Cooler Architecture Overview
- ^ "NASA's James Webb Space Telescope Gets 'Spacewired'" 2007 This article incorporates text from this source, which is in the public domain.
- ^ a b c d e "The Spacecraft Bus". NASA James Webb Space Telescope. 2017. This article incorporates text from this source, which is in the public domain.
- ^ a b "The JWST Observatory". NASA. 2017.
The Observatory is the space-based portion of the James Webb Space Telescope system and is comprisedof three elements: the Integrated Science Instrument Module (ISIM), the Optical Telescope Element (OTE), which includes the mirrors and backplane, and the Spacecraft Element, which includes the spacecraft bus and the sunshield
This article incorporates text from this source, which is in the public domain. - ^ a b "Integrated Science Instrument Module (ISIM)". NASA James Webb Space Telescope. 2017. Archived from the original on 3 December 2016. Retrieved 30 November 2016. This article incorporates text from this source, which is in the public domain.
- ^ a b "JWST vital facts: mission goals". NASA James Webb Space Telescope. 2017. Retrieved 29 January 2017. This article incorporates text from this source, which is in the public domain.
- ^ Sloan, Jeff (12 October 2015). "James Webb Space Telescope spacecraft inches towards full assembly". Composites World.
- ^ "JWST Propulsion". JWST User Documentation. Space Telescope Science Institute. Retrieved 29 December 2021.
- ^ Clark, Stephen (28 November 2021). "NASA gives green light to fuel James Webb Space Telescope". Spaceflight Now.
- ^ a b c McCarthy SG, Autio GW (1978). Infrared Detector Performance In The Shuttle Infrared Telescope Facility (SIRTF). 1978 Los Angeles Technical Symposium. Utilization of Infrared Detectors. Vol. 81. Society of Photographic Instrumentation Engineers. pp. 81–88. Bibcode:1978SPIE..132...81M. doi:10.1117/12.956060.
- ^ "How cold can you go? Cooler tested for NASA telescope". Phys.org. 14 June 2016. Retrieved 31 January 2017.
- ^ "JPL: Herschel Space Observatory: Related Missions". NASA, Jet Propulsion Laboratory, Goddard Flight Center, California Institute of Technology. Retrieved 4 June 2012. This article incorporates text from this source, which is in the public domain.
- ^ "What is ISO?". ESA. 2016. Retrieved 4 June 2021.
- ^ "Hubble Space Telescope – Wide Field Camera 3". NASA. 22 August 2016. This article incorporates text from this source, which is in the public domain.
- ^ a b c d e f g h i j Reichhardt, Tony (March 2006). "US astronomy: Is the next big thing too big?". Nature. 440 (7081): 140–143. Bibcode:2006Natur.440..140R. doi:10.1038/440140a. PMID 16525437.
- ^ "Nexus Space Telescope". MIT.
- ^ a b Haviv Rettig Gur (5 January 2022). "Space is changing. Webb is just the start, says ex-Israeli who was in from its dawn". The Times of Israel. Retrieved 7 January 2022.
- ^ "Advanced Concepts Studies – The 4 m Aperture "Hi-Z" Telescope". NASA Space Optics Manufacturing Technology Center. Archived from the original on 15 October 2011. This article incorporates text from this source, which is in the public domain.
- ^ a b "STSCI JWST History 1994". Archived from the original on 3 February 2014. Retrieved 29 December 2018.
- ^ "Astrononmy and Astrophysics in the New Millennium". NASA. This article incorporates text from this source, which is in the public domain.
- ^ de Weck, Olivier L.; Miller, David W.; Mosier, Gary E. (2002). "Multidisciplinary analysis of the NEXUS precursor space telescope" (PDF). In MacEwen, Howard A. (ed.). Highly Innovative Space Telescope Concepts. Highly Innovative Space Telescope Concepts. Vol. 4849. p. 294. Bibcode:2002SPIE.4849..294D. CiteSeerX 10.1.1.664.8727. doi:10.1117/12.460079. S2CID 18725988.
- ^ "1996swhs.conf..603B Page 603". adsabs.harvard.edu.
- ^ Thronson, H.A.; Hawarden, T.; Davies, J.K.; Lee, T.J.; Mountain, C.M.; Longair, M. (January 1991). "The Edison infrared space observatory and the universe at high redshifts". Advances in Space Research. 11 (2): 341–344. Bibcode:1991AdSpR..11b.341T. doi:10.1016/0273-1177(91)90514-k. ISSN 0273-1177.
- ^ Thronson, Jr., Harley A.; Hawarden, Timothy G.; Bradshaw, Tom W.; Orlowska, Anna H.; Penny, Alan J.; Turner, R. F.; Rapp, Donald (1 November 1993). Bely, Pierre Y; Breckinridge, James B (eds.). "Edison radiatively cooled infrared space observatory". SPIE Proceedings. Space Astronomical Telescopes and Instruments II. 1945. SPIE: 92–99. doi:10.1117/12.158751. S2CID 120232788.
- ^ "Exploration and the Search for Origins: A Vision for Ultraviolet-Optical-Infrared Space Astronomy Report Of The "HST & Beyond" Committee, 1996, ed. A. Dressler, Association of Universities for Research in Astronomy" (PDF).
- ^ The Next Generation Space Telescope. Visiting a time when galaxies were young., by Stockman, H. S.. Space Telescope Science Institute, Baltimore, Maryland. The Association of Universities for Research in Astronomy, Washington, D.C., June 1997
- ^ Astronomy and Astrophysics Survey Committee; Board on Physics and Astronomy; Space Studies Board; Commission on Physical Sciences, Mathematics, and Applications; National Research Council (16 January 2001). Astronomy and Astrophysics in the New Millennium. Washington, D.C.: National Academies Press. doi:10.17226/9839. ISBN 978-0-309-07031-7.
{{cite book}}
: CS1 maint: multiple names: authors list (link) - ^ Goddard Space Flight Center design spacetelescope.org. Retrieved on 13 January 2014
- ^ ESA Science & Technology: Ball Aerospace design for JWST Archived 12 December 2012 at archive.today Sci.esa.int Retrieved on 21 August 2013
- ^ ESA Science & Technology: TRW design for JWST Archived 12 December 2012 at archive.today Sci.esa.int Retrieved on 21 August 2013
- ^ ESA Science & Technology: Lockheed-Martin design for JWST Archived 13 December 2012 at archive.today Sci.esa.int Retrieved on 21 August 2013
- ^ a b "HubbleSite – Webb: Past and Future". Archived from the original on 10 December 2012. Retrieved 13 January 2012.
- ^ "About James Webb". NASA. Retrieved 15 March 2013. This article incorporates text from this source, which is in the public domain.
- ^ "TRW Selected as JWST Prime Contractor". STCI. 11 September 2003. Archived from the original on 5 August 2012. Retrieved 13 January 2012.
- ^ "Northrop Grumman Completes Fabrication Of Sunshield Deployment Flight Structure For JWST". Space Daily. 13 December 2011. Retrieved 10 December 2014.
- ^ a b "European agreement on James Webb Space Telescope's Mid-Infrared Instrument (MIRI) signed" (Press release). ESA Media Relations Service. 9 June 2004. Archived from the original on 18 May 2009. Retrieved 6 May 2009.
- ^ Agency, Canadian Space (4 June 2007). "Canada's contribution to NASA's James Webb Space Telescope". canada.ca. Retrieved 3 July 2021.
- ^ "Canadian Space Agency Delivers Canada's Contributions to the James Webb Space Telescope". SpaceQ. 30 July 2012. Retrieved 3 July 2021.
- ^ "JWST Passes TNAR". STScI. Archived from the original on 5 August 2012. Retrieved 5 July 2008.
- ^ Berger, Brian (23 May 2007). "NASA Adds Docking Capability For Next Space Observatory". SPACE.com. Retrieved 5 July 2008.
- ^ "James Webb Space Telescope sunshield is ready to fabricate". www.laserfocusworld.com. Retrieved 30 December 2021.
- ^ "NASA's Webb Telescope Passes Key Mission Design Review Milestone". NASA. Retrieved 2 May 2010. This article incorporates text from this source, which is in the public domain.
- ^ Clark, Stephen (12 August 2010). "NASA says JWST cost crunch impeding new missions". Spaceflight Now.
- ^ a b c Berardelli, Phil (27 October 1997). "Next Generation Space Telescope will peer back to the beginning of time and space". CBS.
- ^ "NASA's James Webb Space Telescope Primary Mirror Fully Assembled". nasa.gov. 3 February 2016. Retrieved 4 February 2016. This article incorporates text from this source, which is in the public domain.
- ^ "NASA's James Webb Space Telescope Secondary Mirror Installed". NASA. 7 March 2016. Retrieved 23 March 2016. This article incorporates text from this source, which is in the public domain.
- ^ Alan Yuhas (4 November 2016). "Nasa begins testing enormous space telescope made of gold mirrors". The Guardian.
- ^ "NASA Completes Webb Telescope Review, Commits to Launch in Early 2021". NASA. 27 June 2018. Retrieved 27 June 2018. This article incorporates text from this source, which is in the public domain.
- ^ Achenbach, Joel (26 July 2018). "Northrop Grumman CEO is grilled about James Webb Space Telescope errors". The Washington Post. Retrieved 28 December 2019.
- ^ "The two halves of Hubble's US$10 billion successor have finally come together after 12 years of waiting". Business Insider. Retrieved 29 August 2019.
- ^ Clark, Stephen (30 September 2021). "After two decades, the Webb telescope is finished and on the way to its launch site". Spaceflight Now.
{{cite web}}
: CS1 maint: url-status (link) - ^ Wall, Mike (12 October 2021). "NASA's James Webb Space Telescope arrives in French Guiana ahead of December 18 launch". Space.com.
{{cite web}}
: CS1 maint: url-status (link) - ^ "FY 2022 NASA Congressional Budget Justification" (PDF). NASA. p. JWST-2. This article incorporates text from this source, which is in the public domain.
- ^ Foust, Jeff (2 June 2021). "JWST launch slips to November". SpaceNews.
- ^ Lilly, Simon (27 November 1998). "The Next Generation Space Telescope (NGST)". University of Toronto.
- ^ Offenberg, Joel D; Sengupta, Ratnabali; Fixsen, Dale J.; Stockman, Peter; Nieto-Santisteban, Maria; Stallcup, Scott; Hanisch, Robert; Mather, John C. (1999). "Cosmic Ray Rejection with NGST". Astronomical Data Analysis Software and Systems Viii. 172: 141. Bibcode:1999ASPC..172..141O.
- ^ "NGST Weekly Missive". 25 April 2002.
- ^ "NASA Modifies James Webb Space Telescope Contract". 12 November 2003. This article incorporates text from this source, which is in the public domain.
- ^ "Problems for JWST". 21 May 2005.
- ^ "Refocusing NASA's vision". Nature. 440 (7081): 127. 9 March 2006. Bibcode:2006Natur.440..127.. doi:10.1038/440127a. PMID 16525425.
- ^ Cowen, Ron (25 August 2011). "Webb Telescope Delayed, Costs Rise to $8 Billion". ScienceInsider. Archived from the original on 14 January 2012.
- ^ a b "Independent Comprehensive Review Panel, Final Report" (PDF). 29 October 2010. This article incorporates text from this source, which is in the public domain.
- ^ Amos, Jonathan (22 August 2011). "JWST price tag now put at over $8 bn". BBC.
- ^ a b c Moskowitz, Clara (30 March 2015). "NASA Assures Skeptical Congress That the James Webb Telescope Is on Track". Scientific American. Retrieved 29 January 2017.
- ^ "NASA's James Webb Space Telescope to be Launched Spring 2019". NASA. 28 September 2017. This article incorporates text from this source, which is in the public domain.
- ^ a b "NASA Delays Launch of James Webb Space Telescope to 2020". Space.com. Retrieved 27 March 2018.
- ^ "NASA Completes Webb Telescope Review, Commits to Launch in Early 2021". nasa.gov. NASA. 27 June 2018. Retrieved 28 June 2018. This article incorporates text from this source, which is in the public domain.
- ^ "NASA delays launch of Webb telescope to no earlier than Dec. 24". 14 December 2021. Retrieved 14 December 2021. This article incorporates text from this source, which is in the public domain.
- ^ a b Kelly, John (5 June 2011). "Telescope debacle devours NASA funds. Hubble's successor is billions of dollars over budget, 7 years late". Florida Today. Archived from the original on 3 April 2014.
- ^ a b c McKie, Robin (9 July 2011). "Nasa fights to save the James Webb space telescope from the axe". The Guardian. London.
- ^ "Appropriations Committee Releases the Fiscal Year 2012 Commerce, Justice, Science Appropriations". US House of representatives Committee on Appropriations. 6 July 2011. This article incorporates text from this source, which is in the public domain.
- ^ "US lawmakers vote to kill Hubble successor". SpaceDaily. 7 July 2011.
- ^ "Proposed NASA Budget Bill Would Cancel Major Space Telescope". Space.com. 6 July 2011.
- ^ Bergin, Chris (7 January 2015). "James Webb Space Telescope hardware entering key test phase". NASASpaceFlight.com. Retrieved 28 August 2016.
- ^ Hand E. (7 July 2011). "AAS Issues Statement on Proposed Cancellation of James Webb Space Telescope". American Astronomical Society.
- ^ "Mikulski Statement On House Appropriations Subcommittee Termination of James Webb Telescop". SpaceRef. 11 July 2011.
- ^ "Way Above the Shuttle Flight". The New York Times. 9 July 2011.
- ^ Harrold, Max (7 July 2011). "Bad news for Canada: U.S. could scrap new space telescope". The Vancouver Sun.
- ^ "NASA budget plan saves telescope, cuts space taxis". Reuters. 16 November 2011. Archived from the original on 24 September 2015. Retrieved 1 July 2017.
- ^ Leone, Dan (7 November 2012). "NASA Acknowledges James Webb Telescope Costs Will Delay Other Science Missions". SpaceNews.
- ^ Billings, Lee (27 October 2010). "The telescope that ate astronomy". Nature. 467 (7319): 1028–1030. doi:10.1038/4671028a. PMID 20981068.
- ^ Koren, Marina (7 December 2016). "The Extreme Hazing of the Most Expensive Telescope Ever Built". The Atlantic. Retrieved 29 January 2017.
- ^ Wang, Jen Rae; Cole, Steve; Northon, Karen (27 March 2018). "NASA's Webb Observatory Requires More Time for Testing and Evaluation". NASA. Retrieved 27 March 2018. This article incorporates text from this source, which is in the public domain.
- ^ Amos, Jonathan (27 March 2018). "Hubble 'successor' faces new delay". BBC News. Retrieved 27 March 2018.
- ^ Witze, Alexandra (27 March 2018). "NASA reveals major delay for $8-billion Hubble successor". Bibcode:2018Natur.556...11W. doi:10.1038/d41586-018-03863-5. Retrieved 27 March 2018.
- ^ Dreier, Casey (15 February 2019). "NASA just got its best budget in a decade".
- ^ "ESA Science & Technology - Europe's Contributions to the JWST Mission". sci.esa.int.
- ^ "Canadian Space Agency "Eyes" Hubble's Successor: Canada Delivers its Contribution to the World's Most Powerful Space Telescope - Canadian Space Agency". web.archive.org. 12 April 2013.
- ^ a b Jenner, Lynn (1 June 2020). "NASA's Webb Telescope is an International Endeavor". NASA. Retrieved 23 September 2021.
- ^ Shepherd, Tony (25 December 2021). "James Webb: world's most powerful telescope makes its first call to Australia on Christmas Day". the Guardian. Retrieved 5 January 2022.
- ^ "Webb Slinger Heads To Washington". Space Daily. 8 May 2007.
- ^ "Full-Scale Model of the JWST Spacecraft". European Space Agency. 1 September 2019. Retrieved 7 October 2021.
- ^ "NASA's Webb Space Telescope Has Landed in Austin!". NASA. March 2013. Archived from the original on 10 March 2013. This article incorporates text from this source, which is in the public domain.
- ^ Khan, Amina (8 March 2013). "NASA James Webb Space Telescope model lands at South by Southwest". Los Angeles Times.
- ^ "Team Biography of Amber Straughn". Retrieved 20 June 2020. This article incorporates text from this source, which is in the public domain.
- ^ Mark, Juian (13 October 2021). "NASA's James Webb telescope will explore the universe. Critics say its name represents a painful time in U.S. history". The Washington Post. Retrieved 13 October 2021.
- ^ Overbye, Dennis (20 October 2021). "The Webb Telescope's Latest Stumbling Block: Its Name - The long-awaited successor to the Hubble Space Telescope is scheduled to launch in December. But the NASA official for whom it is named has been accused of homophobia". The New York Times. Retrieved 21 October 2021.
- ^ Greenfieldboyce, Nell (30 September 2021). "Shadowed by controversy, NASA won't rename its new space telescope". NPR. Retrieved 27 October 2021.
- ^ Oluseyi, Hakeem (23 January 2021). "Was NASA's Historic Leader James Webb a Bigot?". Medium. Retrieved 18 November 2021.
{{cite web}}
: CS1 maint: url-status (link) - ^ B.L.S, Amrit (22 October 2021). "After NASA Refuses To Rename James Webb Telescope, Advisor Quits in Protest".
- ^ Maggie Masetti; Anita Krishnamurthi (2009). "JWST Science". NASA. Retrieved 14 April 2013. This article incorporates text from this source, which is in the public domain.
- ^ "NASA's Next Telescope Could ID Alien Megastructures". 9 February 2016. Retrieved 1 September 2016.
- ^ "Basics of Space Flight". Jet Propulsion Laboratory. Retrieved 28 August 2016. This article incorporates text from this source, which is in the public domain.
- ^ Donald J. Dichmann, Cassandra M. Alberding, Wayne H. Yu (5 May 2014). "STATIONKEEPING MONTE CARLO SIMULATION FOR THE JAMES WEBB SPACE TELESCOPE" (PDF). NASA Goddard Space Flight Center. Archived from the original (PDF) on 17 December 2021. Retrieved 29 December 2021.
{{cite web}}
: CS1 maint: multiple names: authors list (link) This article incorporates text from this source, which is in the public domain. - ^ Matt Greenhouse. "JWST Project Report to the PMC" (PDF). NASA Goddard Space Flight Center.
- ^ "James Webb Space Telescope Initial Mid-Course Correction Monte Carlo Implementation using Task Parallelism" 3.1 Propulsion System Overview. J. Petersen et al. This article incorporates text from this source, which is in the public domain.
- ^ Kimble, Randy (27 December 2021). "More Than You Wanted to Know About Webb's Mid-Course Corrections!". NASA. Retrieved 27 December 2021. This article incorporates text from this source, which is in the public domain.
- ^ Howard, Rick, "James Webb Space Telescope (JWST)", nasa.gov, 6 March 2012 This article incorporates text from this source, which is in the public domain.
- ^ "Infrared Atmospheric Windows". Cool Cosmos. Retrieved 28 August 2016.
- ^ a b c d "Infrared Astronomy: Overview". NASA Infrared Astronomy and Processing Center. Archived from the original on 8 December 2006. Retrieved 30 October 2006. This article incorporates text from this source, which is in the public domain.
- ^ a b "Webb Science: The End of the Dark Ages: First Light and Reionization". NASA. Retrieved 9 June 2011. This article incorporates text from this source, which is in the public domain.
- ^ a b c d Mather, John (13 June 2006). "James Webb Space Telescope (JWST) Science Summary for SSB" (PDF). NASA. Retrieved 4 June 2021. This article incorporates text from this source, which is in the public domain.
- ^ "Webb Spacecraft Science & Operations Center Contract Awarded". NASA. 6 June 2003. Retrieved 1 February 2017.
{{cite web}}
: Unknown parameter|authors=
ignored (help) This article incorporates text from this source, which is in the public domain. - ^ "Single Board Computer". FBO Daily Issue, FBO #0332. 30 October 2002.
- ^ a b "Amazing Miniaturized 'SIDECAR' Drives Webb Telescope's Signal". NASA. 20 February 2008. Retrieved 22 February 2008. This article incorporates text from this source, which is in the public domain.
- ^ Overbye, Dennis; Roulette, Joey (25 December 2021). "James Webb Space Telescope Launches on Journey to See the Dawn of Starlight". The New York Times. ISSN 0362-4331. Retrieved 25 December 2021.
- ^ "How to track James Webb Space Telescope, mission timeline". Space Explored. 31 December 2021. Retrieved 1 January 2022.
- ^ "James Webb Space Telescope". blogs.nasa.gov.
- ^ "About the Webb". NASA James Webb Space Telescope. 2017. This article incorporates text from this source, which is in the public domain.
- ^ a b "Frequently asked questions: How long will the Webb mission last?". NASA James Webb Space Telescope. 2017. This article incorporates text from this source, which is in the public domain.
- ^ "JWST Orbit". James Webb Space Telescope User Documentation. Retrieved 8 September 2021.
- ^ a b Fox, Karen. "NASA Says Webb's Excess Fuel Likely to Extend its Lifetime Expectations". James Webb Space Telescope (NASA Blogs). Retrieved 30 December 2021.
- ^ Berger, Eric (10 January 2022). "All hail the Ariane 5 rocket, which doubled the Webb telescope's lifetime". www.arstechnica.com. Ars Technica. Retrieved 11 January 2022.
- ^ Amos, Jonathan (9 January 2022). "James Webb telescope completes epic deployment sequence". www.bbc.com. BBC News. Retrieved 10 January 2022.
- ^ Camera on ESC-D Cryotechnic upper stage (25 Dec 2021) view of newly separated JWST, as seen from the ESC-D Cryotechnic upper stage
- ^ James Webb Space Telescope Deployment Sequence (Nominal), pp. 1:47, archived from the original on 23 December 2021, retrieved 23 December 2021
- ^ Warren, Haygen (27 December 2021). "James Webb Space Telescope en route to L2; deployment sequence underway". NASA spaceflight.com. Retrieved 5 January 2022.
- ^ Achenbach, Joel (4 January 2022). "NASA thrilled: Webb Space Telescope deploys sun shield, evades many potential 'single-point failures'". The Washington Post. Retrieved 5 January 2022.
- ^ a b c "Gimbaled Antenna Assembly". James Webb Space Telescope. NASA. Retrieved 27 December 2021.
- ^ https://mobile.twitter.com/Dr_ThomasZ/status/1475018804187086850 [bare URL]
- ^ Schultz, Isaac (6 January 2022). "New Video Shows Webb Space Telescope's Goodbye to Earth". Gizmodo. Retrieved 7 January 2022.
- ^ a b c d Media Briefing: Webb Telescope Week One Deployments Update, retrieved 3 January 2022
- ^ Fox, Karen. "The First Mid-Course Correction Burn". NASA Blogs. Retrieved 27 December 2021.
- ^ Fox, Karen. "Webb's Second Mid-Course Correction Burn". James Webb Space Telescope (NASA Blogs). Retrieved 29 December 2021.
- ^ Fisher, Alise. "Forward Pallet Structure Lowered, Beginning Multiple-Day Sunshield Deployment". James Webb Space Telescope (NASA Blogs). Retrieved 29 December 2021.
- ^ Fisher, Alise. "Aft Sunshield Pallet Deployed". James Webb Space Telescope (NASA Blogs). Retrieved 29 December 2021.
- ^ Fisher, Alise. "Webb Team Begins Process of Extending Deployable Tower Assembly". James Webb Space Telescope (NASA Blogs). Retrieved 30 December 2021.
- ^ Fisher, Alise. "Webb's Deployable Tower Assembly Extends in Space". James Webb Space Telescope (NASA Blogs). Retrieved 30 December 2021.
- ^ Fisher, Alise. "Webb's Aft Momentum Flap Deployed". James Webb Space Telescope (NASA Blogs). Retrieved 31 December 2021.
- ^ Fisher, Alise. "Webb Team Releases Sunshield Covers". James Webb Space Telescope (NASA Blogs). Retrieved 31 December 2021.
- ^ a b c Lynch, Patrick (31 December 2021). "With Webb's Mid-Booms Extended, Sunshield Takes Shape". James Webb Space Telescope (NASA Blogs). Retrieved 1 January 2022.
- ^ a b Lynch, Patrick (31 December 2021). "First of Two Sunshield Mid-Booms Deploys". James Webb Space Telescope (NASA Blogs). Retrieved 1 January 2022.
- ^ Zastrow, Mark (5 January 2022). "James Webb Space Telescope successfully deploys sunshield". astronomy.com. Retrieved 5 January 2022.
- ^ Fox, Karen (3 January 2022). "First Layer of Webb's Sunshield Tightened". James Webb Space Telescope (NASA Blogs). Retrieved 4 January 2022.
- ^ Lynch, Patrick (3 January 2022). "Second and Third Layers of Sunshield Fully Tightened". James Webb Space Telescope (NASA Blogs). Retrieved 4 January 2022.
- ^ Fox, Karen (4 January 2022). "Webb Team Tensions Fifth Layer, Sunshield Fully Deployed". James Webb Space Telescope (NASA Blogs). Retrieved 5 January 2022.
- ^ Fisher, Alise (5 January 2022). "Secondary Mirror Deployment Confirmed". James Webb Space Telescope (NASA Blogs. Retrieved 6 January 2022.
- ^ Alise Fisher (7 January 2022). "First of Two Primary Mirror Wings Unfolds – James Webb Space Telescope". blogs.nasa.gov | James Webb Space Telescope. Retrieved 8 January 2022.
- ^ Alise Fisher (8 January 2022). "Primary Mirror Wings Deployed, All Major Deployments Complete". James Webb Space Telescope (NASA Blogs). Retrieved 8 January 2022.
- ^ Berger, Eric (8 January 2022). "Remarkably, NASA has completed deployment of the Webb space telescope". cansciencenews.com. Retrieved 8 January 2022.
- ^ "Space telescope's 'golden eye' opens, last major hurdle". phys.org. 8 January 2022. Retrieved 9 January 2022.
- ^ "James Webb Space Telescope – The First 30 Days After Launch". News Ledge. 3 March 2017.
- ^ a b https://blogs.nasa.gov/webb/2022/01/12/webb-begins-its-months-long-mirror-alignment
- ^ a b c https://blogs.nasa.gov/webb/2022/01/13/mirror-mirroron-its-way/
- ^ "Calls for Proposals & Policy". Space Telescope Science Institute. Retrieved 13 November 2017. This article incorporates text from this source, which is in the public domain.
- ^ "Selections Made for the JWST Director's Discretionary Early Release Science Program". Space Telescope Science Institute. Archived from the original on 8 August 2018. Retrieved 13 November 2017. This article incorporates text from this source, which is in the public domain.
- ^ "Director's Discretionary Early Release Science Programs". Space Telescope Science Institute. Retrieved 26 December 2021.
- ^ "JWST Cycle 1 General Observer Submission Statistics". Space Telescope Science Institute. Retrieved 10 January 2022.
- ^ "STScI Announces the JWST Cycle 1 General Observer Program". Retrieved 30 March 2021.
Further reading
- Jonathan P. Gardner; et al. (November 2006). "The James Webb Space Telescope". Space Science Reviews. 123 (4): 484–606. arXiv:astro-ph/0606175. Bibcode:2006SSRv..123..485G. doi:10.1007/s11214-006-8315-7. S2CID 118865272. The formal case for JWST science presented in 2006.
- Jason Kalirai (April 2018). "Scientific discovery with the James Webb Space Telescope". Contemporary Physics. 59 (3): 259–290. arXiv:1805.06941. Bibcode:2018ConPh..59..251K. doi:10.1080/00107514.2018.1467648. S2CID 85539627. A review of JWST capabilities and scientific opportunities.
External links
- Official NASA website / Official STScI website / Official French website
- JWST NASA – *TRACKING* page − from Launch to L2 (second Lagrangian point)
- JWST NASA – About page − Timeline details / Webb orbit / L2 / Communicating
- JWST Text – Most Critical Events – Launching and Deployment (December 2021)
- JWST Video (031:22): Highlights − Technical Engineering Details (December 2021)
- JWST Video (012:02): 1st Month – Launching and Deployment (animation; January 2017)
- JWST Video (008:06): 1st Month − Launching and Deployment (update; October 2021)
- JWST Videos (Mission Control Live) – Deployment Events − Now Successfully Completed:
- LAUNCH (005:07; 25 Dec 2021) => SEPARATION (003:14; 25 Dec 2021) (mirror) => SUNSHIELD (152:45; 04 Jan 2022) =>
- SECONDARY MIRROR (087:15; 05 Jan 2022) => PRIMARY MIRROR (242:29; 08 Jan 2022) => FINAL DEPLOYMENT DONE (085:15; 08 Jan 2022) =>
- CRUISE TO L2 (ongoing; 000:19; Jan 2022) => TESTINGS & CALIBRATIONS (ongoing; 007:14; Jan-Jun 2022) => FIRST LIGHT (ongoing; 007:30; Mar-Jun 2022)
- Articles with bare URLs for citations from December 2021
- Current events from December 2021
- 2024 in spaceflight
- James Webb Space Telescope
- 2021 in science
- Spacecraft launched in 2021
- Spacecraft launched by Ariane rockets
- European Space Agency space probes
- Exoplanet search projects
- Goddard Space Flight Center
- Infrared telescopes
- NASA programs
- Northrop Grumman spacecraft
- NASA space probes
- Space program of Canada
- Space telescopes
- Spacecraft using halo orbits
- 2021 in French Guiana
- Naming controversies
- LGBT-related controversies
- Artificial satellites at Earth-Sun Lagrange points