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Shuttle–Mir program

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Shuttle–Mir program
Программа «Мир» — «Шаттл»
Program overview
Country
Organization
StatusCompleted
Program history
First flightFebruary 3, 1994 (STS-60)
Last flightJune 2, 1998 (STS-91)
Launch site(s)
Vehicle information
Crewed vehicle(s)

The Shuttle–Mir program (Russian: Программа «Мир»–«Шаттл»)[a] was a collaborative space program between Russia and the United States that involved American Space Shuttles visiting the Russian space station Mir, Russian cosmonauts flying on the Shuttle, and an American astronaut flying aboard a Soyuz spacecraft to allow American astronauts to engage in long-duration expeditions aboard Mir.

The project, sometimes called "Phase One", was intended to allow the United States to learn from Russian experience with long-duration spaceflight and to foster a spirit of cooperation between the two nations and their space agencies, the National Aeronautics and Space Administration (NASA) and the Russian Space Agency (PKA). The project helped to prepare the way for further cooperative space ventures; specifically, "Phase Two" of the joint project, the construction of the International Space Station (ISS). The program was announced in 1993, the first mission started in 1994 and the project continued until its scheduled completion in 1998. Eleven Space Shuttle missions, a joint Soyuz flight and almost 1,000 cumulative days in space for American astronauts occurred over the course of seven long-duration expeditions. In addition to Space Shuttle launches to Mir the United States also fully funded and equipped with scientific equipment the Spektr module (launched in 1995) and the Priroda module (launched in 1996), making them de facto U.S. modules during the duration of the Shuttle-Mir program.[1]

During the four-year program, many firsts in spaceflight were achieved by the two nations, including the first American astronaut to launch aboard a Soyuz spacecraft, the largest spacecraft ever to have been assembled at that time in history, and the first American spacewalk using a Russian Orlan spacesuit.

The program was marred by various concerns, notably the safety of Mir following a fire, a Russian spacecraft colliding with Spektr rendering it uninhabitable, financial issues with the cash-strapped Russian space program and worries from astronauts about the attitudes of the program administrators. Nevertheless, a large amount of science, expertise in space station construction and knowledge in working in a cooperative space venture was gained from the combined operations, allowing the construction of the ISS to proceed much more smoothly than would have otherwise been the case.

Background

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A "Shuttle–Salyut" program was proposed in the 1970s, yet never realized. This rendering depicts a Space Shuttle docked to a second-generation Salyut space station, with a Soyuz spacecraft docked to Salyut's aft port.

The origins of the Shuttle–Mir program can be traced back to the 1975 Apollo–Soyuz Test Project, that resulted in a joint US/Soviet mission during the détente period of the Cold War and the docking between a US Apollo spacecraft and a Soviet Soyuz spacecraft. This was followed by the talks between NASA and Intercosmos in the 1970s about a "Shuttle–Salyut" program to fly Space Shuttle missions to a Salyut space station, with later talks in the 1980s even considering flights of the future Soviet shuttles from the Buran programme to a future US space station – this "Shuttle–Salyut" program never materialized however during the existence of the Soviet Intercosmos program.[2]

This changed after the Dissolution of the Soviet Union: the end of Cold War and Space Race resulted in funding for the US modular space station (originally named Freedom), which was planned since the early 1980s, being slashed.[3] Similar budgetary difficulties were being faced by other nations with space station projects, prompting American government officials to start negotiations with partners in Europe, Russia, Japan, and Canada in the early 1990s to begin a collaborative, multi-national, space station project.[3] In the Russian Federation, as the successor to much of the Soviet Union and its space program, the deteriorating economic situation in the post-Soviet economic chaos led to growing financial problems of the now Russian space station program. The construction of the Mir-2 space station as a replacement for the aging Mir became illusionary, though only after its base block, DOS-8, had been built.[3] These developments resulted in bringing the former adversaries together with the Shuttle–Mir Program, which would pave the way to the International Space Station, a joint project with several international partners.[4]

A cluster of cylindrical modules with projecting feathery solar arrays and a spaceplane docked to the lower module. In the background is the blackness of space, and in the lower right corner is Earth.
Space Shuttle Atlantis docked to Mir on STS-71

In June 1992, American President George H. W. Bush and Russian president Boris Yeltsin agreed to co-operate on space exploration by signing the Agreement between the United States of America and the Russian Federation Concerning Cooperation in the Exploration and Use of Outer Space for Peaceful Purposes. This agreement called for setting up a short, joint space project, during which one American astronaut would board the Russian space station Mir and two Russian cosmonauts would board a Space Shuttle.[3]

In September 1993, American Vice-President Al Gore Jr., and Russian Prime Minister Viktor Chernomyrdin announced plans for a new space station, which eventually became the International Space Station.[5] They also agreed, in preparation for this new project, that the United States would be heavily involved in the Mir project in the years ahead, under the code name "Phase One" (the construction of the ISS being "Phase Two").[6]

The first Space Shuttle flight to Mir was a rendezvous mission without docking on STS-63. This was followed during the course of the project by nine Shuttle–Mir docking missions, from STS-71 to STS-91. The Shuttle rotated crews and delivered supplies, and one mission, STS-74, carried a docking module and a pair of solar arrays to Mir. Various scientific experiments were also conducted, both on shuttle flights and long-term aboard the station. The project also saw the launch of two new modules, Spektr and Priroda, to Mir, which were used by American astronauts as living quarters and laboratories to conduct the majority of their science aboard the station. These missions allowed NASA and Roscosmos to learn a great deal about how best to work with international partners in space and how to minimize the risks associated with assembling a large space station in orbit, as would have to be done with the ISS.[7][8]

The project also served as a political ruse on the part of the American government, providing a diplomatic channel for NASA to take part in the funding of the cripplingly under-funded Russian space program. This in turn allowed the newly fledged Russian government to keep Mir operating, in addition to the Russian space program as a whole, ensuring the Russian government remained friendly towards the United States.[9][10]

Increments

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A portrait of six men and one woman, arranged in two rows, four sitting at the front and three standing at the back. They are each wearing tan trousers and a blue polo shirt with a patch and their name on it, and the US and NASA flags are visible in the background.
The seven American astronauts who carried out long-duration Increments on Mir

In addition to the flights of the Shuttle to Mir, Phase One also featured seven "Increments" aboard the station, long-duration flights aboard Mir by American astronauts. The seven astronauts who took part in the Increments, Norman Thagard, Shannon Lucid, John Blaha, Jerry Linenger, Michael Foale, David Wolf and Andrew Thomas, were each flown in turn to Star City, Russia, to undergo training in various aspects of the operation of Mir and the Soyuz spacecraft used for transport to and from the Station. The astronauts also received practice in carrying out spacewalks outside Mir and lessons in the Russian language, which would be used throughout their missions to talk with the other cosmonauts aboard the station and Mission Control in Russia, the TsUP.[10]

During their expeditions aboard Mir, the astronauts carried out various experiments, including growth of crops and crystals, and took hundreds of photographs of the Earth. They also assisted in the maintenance and repair of the aging station, following various incidents with fires, collisions, power losses, uncontrolled spins and toxic leaks. In all, the American astronauts would spend almost a thousand days aboard Mir, allowing NASA to learn a great deal about long-duration spaceflight, particularly in the areas of astronaut psychology and how best to arrange experiment schedules for crews aboard space stations.[9][10]

Mir

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A cluster of cylindrical modules with projecting feathery solar arrays, with Earth's horizon visible in the background.
The view of Mir from Space Shuttle Discovery in 1998 as it left the station during STS-91

Mir was constructed between 1986 and 1996 and was the world's first modular space station. It was the first consistently inhabited long-term research station in space, and previously held the record for longest continuous human presence in space, at eight days short of ten years. Mir's purpose was to provide a large and habitable scientific laboratory in space, and, through a number of collaborations, including Intercosmos and Shuttle–Mir, was made internationally accessible to cosmonauts and astronauts of many different countries. The station existed until March 23, 2001, at which point it was deliberately deorbited, and broke apart during atmospheric re-entry.[3]

Mir was based upon the Salyut series of space stations previously launched by the Soviet Union (seven Salyut space stations had been launched since 1971), and was mainly serviced by Russian-crewed Soyuz spacecraft and Progress cargo ships. The Buran space shuttle was anticipated to visit Mir, but its program was canceled after its first uncrewed spaceflight. Visiting US Space Shuttles used an Androgynous Peripheral Attach System docking collar originally designed for Buran, mounted on a bracket originally designed for use with the American Space Station Freedom.[3]

With the Space Shuttle docked to Mir, the temporary enlargements of living and working areas amounted to a complex that was the world's largest spacecraft at that time, with a combined mass of 250 metric tons (250 long tons; 280 short tons).[3][11]

Space Shuttle

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An overhead view of a spaceplane, coloured white on its topside and black on its underside, attached to a large orange tank, to which two slender white rockets are also attached. A gray platform supporting this stack serves as the background.
An overhead view of Atlantis as it sits atop the Mobile Launcher Platform (MLP) before STS-79

The Space Shuttle was a partially reusable low Earth orbital spacecraft system that was operated from 1981 to 2011 by the U.S. National Aeronautics and Space Administration (NASA) as part of the Space Shuttle program. Its official program name was Space Transportation System (STS), taken from a 1969 plan for a system of reusable spacecraft of which it was the only item funded for development.[12] The first of four orbital test flights occurred in 1981, leading to operational flights beginning in 1982. In addition to the prototype, whose completion was cancelled, five complete Shuttle systems were built and used on a total of 135 missions from 1981 to 2011, launched from the Kennedy Space Center (KSC) in Florida. The Shuttle fleet's total mission time was 1322 days, 19 hours, 21 minutes and 23 seconds.[13]

The Space Shuttle carried large payloads to various orbits, and, during the Shuttle–Mir and ISS programs, provided crew rotation and carried various supplies, modules and pieces of equipment to the stations. Each Shuttle was designed for a projected lifespan of 100 launches or 10 years' operational life.[14][15]

Nine docking missions were flown to Mir, from 1995 to 1997 during "Phase One": Space Shuttle Atlantis docked seven times to Mir, with Discovery and Endeavour each flying one docking mission to Mir. As Space Shuttle Columbia was the oldest and heaviest of the fleet, it was not suited for efficient operations at Mir's (and later the ISS's) 51.6-degree inclination – Columbia was therefore not retrofitted with the necessary external airlock and Orbital Docking System, and never flew to a space station.[16][17][18]

Timeline

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A space shuttle launches into a dawn sky. Clouds in the sky, in the launch plume and from the flame trench, are visible, as is the scaffolding-like launchpad and some vegetation silhouetted in the foreground.
The Shuttle–Mir program begins—Discovery launches on STS-60, the first flight of the program.

New cooperation begins (1994)

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Phase One of the Shuttle–Mir program began on February 3, 1994, with the launch of Space Shuttle Discovery on its 18th mission, STS-60. The eight-day mission was the first shuttle flight of that year, the first flight of a Russian cosmonaut, Sergei Krikalev, aboard the American shuttle, and marked the start of increased cooperation in space for the two nations, 37 years after the Space Race began.[19] Part of an international agreement on human space flight, the mission was the second flight of the Spacehab pressurized module and marked the hundredth "Getaway Special" payload to fly in space. The primary payload for the mission was the Wake Shield Facility (or WSF), a device designed to generate new semiconductor films for advanced electronics. The WSF was flown at the end of Discovery's robotic arm over the course of the flight. During the mission, the astronauts aboard Discovery also carried out various experiments aboard the Spacehab module in the Orbiter's payload bay, and took part in a live bi-directional audio and downlink video hookup between themselves and the three cosmonauts on board Mir, Valeri Polyakov, Viktor Afanasyev and Yury Usachev (flying Mir expeditions LD-4 and EO-15).[16][20][21]

A cluster of modules and feathery solar arrays floats in the middle distance before an image of the Earth and the blackness of space above its horizon. Sunrays project from the top centre of the image.
A view of Mir following Atlantis's undocking at the end of STS-71

America arrives at Mir (1995)

[edit]

1995 began with the launch of the Space Shuttle Discovery on February 3. Discovery's mission, STS-63, was the second Space Shuttle flight in the program and the first flight of the shuttle with a female pilot, Eileen Collins. Referred to as the "near-Mir" mission, the eight-day flight saw the first rendezvous of a Space Shuttle with Mir, as Russian cosmonaut Vladimir Titov and the rest of Discovery's crew approached within 37 feet (11 m) of Mir. Following the rendezvous, Collins performed a flyaround of the station. The mission, a dress rehearsal for the first docked mission in the program, STS-71, also carried out testing of various techniques and pieces of equipment that would be used during the docking missions that followed.[20][22][23]

Five weeks after Discovery's flight, the March 14 launch of Soyuz TM-21 carried expedition EO-18 to Mir. The crew consisted of cosmonauts Vladimir Dezhurov and Gennady Strekalov and NASA astronaut Norman Thagard, who became the first American to fly into space aboard the Soyuz spacecraft. During the course of their 115-day expedition, the Spektr science module (which served as living and working space for American astronauts) was launched aboard a Proton rocket and docked to Mir. Spektr carried more than 1,500 pounds (680 kg) of research equipment from America and other nations. The expedition's crew returned to Earth aboard Space Shuttle Atlantis following the first Shuttle–Mir docking during mission STS-71.[3][9][24]

A space shuttle payload bay, covered in white insulation, with a small, cylindrical orange module at one end, supported by the shuttle's robotic arm. The blackness of space and the Earth serve as the backdrop.
The Mir Docking Module, positioned in Atlantis's payload bay on STS-74, ready to be docked to Kristall

The primary objectives of STS-71, launched on June 27, called for the Space Shuttle Atlantis to rendezvous and perform the first docking between an American Space Shuttle and the station. On June 29, Atlantis successfully docked with Mir, becoming the first US spacecraft to dock with a Russian spacecraft since the Apollo-Soyuz Test Project in 1975.[25] Atlantis delivered cosmonauts Anatoly Solovyev and Nikolai Budarin, who would form the expedition EO-19 crew, and retrieved astronaut Norman Thagard and cosmonauts Vladimir Dezhurov and Gennady Strekalov of the expedition EO-18 crew. Atlantis also carried out on-orbit joint US-Russian life sciences investigations aboard a Spacelab module and performed a logistical resupply of the station.[20][26][27]

The final Shuttle flight of 1995, STS-74, began with the November 12 launch of Space Shuttle Atlantis, and delivered the Russian-built Docking Module to Mir, along with a new pair of solar arrays and other hardware upgrades for the station. The Docking Module was designed to provide more clearance for Shuttles in order to prevent any collisions with Mir's solar arrays during docking, a problem which had been overcome during STS-71 by relocating the station's Kristall module to a different location on the station. The module, attached to Kristall's docking port, prevented the need for this procedure on further missions. During the course of the flight, nearly 1,000 pounds (450 kg) of water were transferred to Mir and experiment samples including blood, urine and saliva were moved to Atlantis for return to Earth.[20][28][29][30]

A rectangular dish shape of scaffolding covered in transparent sheeting, with a white insulation-covered radio receiver and support projecting from the centre. The blackness of space serves as the backdrop.
A view of the Travers RADAR antenna on the newly launched Priroda module during STS-79

Priroda (1996)

[edit]

Continuous US presence aboard Mir started in 1996 with the March 22 launch of Atlantis on mission STS-76, when the Second Increment astronaut Shannon Lucid was transferred to the station. STS-76 was the third docking mission to Mir, which also demonstrated logistics capabilities through deployment of a Spacehab module, and placed experiment packages aboard Mir's docking module, which marked the first spacewalk which occurred around docked vehicles. The spacewalks, carried out from Atlantis's crew cabin, provided valuable experience for astronauts in order to prepare for later assembly missions to the International Space Station.[31]

Lucid became the first American woman to live on station, and, following a six-week extension to her Increment due to issues with Shuttle Solid Rocket Boosters, her 188-day mission set the US single spaceflight record. During Lucid's time aboard Mir, the Priroda module, with about 2,200 pounds (1,000 kg) of US science hardware, was docked to Mir. Lucid made use of both Priroda and Spektr to carry out 28 different science experiments and as living quarters.[20][32]

A view showing a module covered in white insulation with a smaller module, covered in orange insulation, connected to the end of it. Part of a space shuttle can be seen attached to the orange module, and a number of folded and unfolded solar arrays are visible. The limb of the Earth forms the backdrop.
Space Shuttle Atlantis docked to Mir during STS-81. The crew compartment, nose and a portion of the payload bay of Atlantis are visible, behind Mir's Kristall and Docking Modules.

Her stay aboard Mir ended with the flight of Atlantis on STS-79, which launched on September 16. STS-79 was the first Shuttle mission to carry a double Spacehab module. More than 4,000 pounds (1,800 kg) of supplies were transferred to Mir, including water generated by Atlantis's fuel cells, and experiments that included investigations into superconductors, cartilage development, and other biology studies. About 2,000 pounds (910 kg) of experiment samples and equipment were also transferred back from Mir to Atlantis, making the total transfer the most extensive yet.[33]

This, the fourth docking, also saw John Blaha transferring onto Mir to take his place as resident Increment astronaut. His stay on the station improved operations in several areas, including transfer procedures for a docked space shuttle, "hand-over" procedures for long-duration American crew members and "Ham" amateur radio communications.

Two spacewalks were carried out during his time aboard. Their aim was to remove electrical power connectors from a 12-year-old solar power array on the base block and reconnect the cables to the more efficient new solar power arrays. In all, Blaha spent four months with the Mir-22 cosmonaut crew conducting material science, fluid science, and life science research, before returning to Earth the next year aboard Atlantis on STS-81.[20][34]

Fire and collision (1997)

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A white panel covered in buttons, which shows signs of fire damage on its bottom edge. Wiring and other pieces of hardware are arrayed beneath the panel.
A charred panel onboard Mir following the fire

In 1997 STS-81 replaced Increment astronaut John Blaha with Jerry Linenger, after Blaha's 118-day stay aboard Mir. During this fifth shuttle docking, the crew of Atlantis moved supplies to the station and returned to Earth the first plants to complete a life cycle in space; a crop of wheat planted by Shannon Lucid. During five days of mated operations, the crews transferred nearly 6,000 pounds (2,700 kg) of logistics to Mir, and transferred 2,400 pounds (1,100 kg) of materials back to Atlantis (the most materials transferred between the two spacecraft to that date).[35]

The STS-81 crew also tested the Shuttle Treadmill Vibration Isolation and Stabilization System (TVIS), designed for use in the Zvezda module of the International Space Station. The shuttle's small vernier jet thrusters were fired during the mated operations to gather engineering data for "reboosting" the ISS. After undocking, Atlantis performed a fly-around of Mir, leaving Linenger aboard the station.[20][35]

Picture of the damage caused by the collision with Progress M-34, taken by Atlantis during STS-86

During his Increment, Linenger became the first American to conduct a spacewalk from a foreign space station and the first to test the Russian-built Orlan-M spacesuit alongside Russian cosmonaut Vasili Tsibliyev. All three crewmembers of expedition EO-23 performed a "fly-around" in the Soyuz spacecraft, first undocking from one docking port of the station, then manually flying to and redocking the capsule at a different location. This made Linenger the first American to undock from a space station aboard two different spacecraft (Space Shuttle and Soyuz).[24]

Linenger and his Russian crewmates Vasili Tsibliyev and Aleksandr Lazutkin faced several difficulties during the mission. These included the most severe fire aboard an orbiting spacecraft (caused by a backup oxygen-generating device), failures of various on board systems, a near collision with a Progress resupply cargo ship during a long-distance manual docking system test and a total loss of station electrical power. The power failure also caused a loss of attitude control, which led to an uncontrolled "tumble" through space.[3][9][10][20]

The next NASA astronaut to stay on Mir was Michael Foale. Foale and Russian mission specialist Elena Kondakova boarded Mir from Atlantis on mission STS-84. The STS-84 crew transferred 249 items between the two spacecraft, along with water, experiment samples, supplies and hardware. One of the first items transferred to Mir was an Elektron oxygen-generating unit. Atlantis was stopped three times while backing away during the undocking sequence on May 21. The aim was to collect data from a European sensor device designed for future rendezvous of ESA's Automated Transfer Vehicle (ATV) with the International Space Station.[20][36]

A gold-coloured solar array, bent and twisted out of shape and with several holes. The edge of a module can be seen to the right of the image, and Earth is visible in the background.
Damaged solar arrays on Mir's Spektr module following a collision with an uncrewed Progress spacecraft in September 1997

Foale's Increment proceeded fairly normally until June 25, when a resupply ship collided with solar arrays on the Spektr module during the second test of the Progress manual docking system, TORU. The module's outer shell was hit and holed, which caused the station to lose pressure. This was the first on-orbit depressurization in the history of spaceflight. The crew quickly cut cables leading to the module and closed Spektr's hatch in order to prevent the need to abandon the station in their Soyuz lifeboat. Their efforts stabilized the station's air pressure, whilst the pressure in Spektr, containing many of Foale's experiments and personal effects, dropped to a vacuum. Fortunately, food, water and other vital supplies were stored in other modules, and salvage and replanning effort by Foale and the science community minimized the loss of research data and capability.[9][20]

In an effort to restore some of the power and systems lost following the isolation of Spektr and to attempt to locate the leak, Mir's new commander Anatoly Solovyev and flight engineer Pavel Vinogradov carried out a salvage operation later in the mission. They entered the empty module during a so-called "IVA" spacewalk, inspecting the condition of hardware and running cables through a special hatch from Spektr's systems to the rest of the station. Following these first investigations, Foale and Solovyev conducted a 6-hour EVA on the surface of Spektr to inspect the damaged module.[20][37]

A cluster of modules, covered in white insulation and projecting feathery solar arrays, with a small spacecraft covered in brown insulation docked at their centre. The image is seen through a window, with the blackness of space and the Earth forming the backdrop.
A view of Mir from Atlantis's window, showing several of the station's modules and the docked Soyuz capsule

After these incidents, the US Congress and NASA considered whether to abandon the program out of concern for astronauts' safety but NASA administrator Daniel Goldin decided to continue the program.[10] The next flight to Mir, STS-86, brought Increment astronaut David Wolf to the station.

STS-86 performed the seventh Shuttle–Mir docking, the last of 1997. During Atlantis's stay crew members Titov and Parazynski conducted the first joint US–Russian extravehicular activity during a Shuttle mission, and the first in which a Russian wore a US spacesuit. During the five-hour spacewalk, the pair affixed a 121-pound (55 kg) Solar Array Cap to the Docking Module, for a future attempt by crew members to seal off the leak in Spektr's hull. The mission returned Foale to Earth, along with samples, hardware, and an old Elektron oxygen generator, and dropped Wolf off on the Station ready for his 128-day Increment. Wolf had originally been scheduled to be the final Mir astronaut, but was chosen to go on the Increment instead of astronaut Wendy Lawrence. Lawrence was deemed ineligible for flight because of a change in Russian requirements after the Progress supply vehicle collision. The new rules required that all Mir crew members should be trained and ready for spacewalks, but a Russian spacesuit could not be prepared for Lawrence in time for launch.[20][38]

A spaceplane, coloured white on its topside and black on its underside, lands on a runway. A strip of turf is visible in the foreground, there are trees in the background and there is a cloud of smoke coming from the spaceplane's rear wheels.
Space Shuttle Discovery lands at the end of STS-91 on 12 June 1998, bringing the Shuttle–Mir program to a close.

Phase One closes down (1998)

[edit]

The final year of Phase One began with the flight of Space Shuttle Endeavour on STS-89. The mission delivered cosmonaut Salizhan Sharipov to Mir and replaced David Wolf with Andy Thomas, following Wolf's 119-day Increment.[20][39]

During his Increment, the last of the program, Thomas worked on 27 science investigations into areas of advanced technology, Earth sciences, human life sciences, microgravity research, and ISS risk mitigation. His stay on Mir, considered the smoothest of the entire Phase One program, featured weekly "Letters from the Outpost" from Thomas and passed two milestones for length of spaceflight—815 consecutive days in space by American astronauts since the launch of Shannon Lucid on the STS-76 mission in March 1996, and 907 days of Mir occupancy by American astronauts dating back to Norman Thagard's trip to Mir in March 1995.[20][40]

Thomas returned to Earth on the final Shuttle–Mir mission, STS-91. The mission closed out Phase One, with the EO-25 and STS-91 crews transferring water to Mir and exchanging almost 4,700 pounds (2,100 kg) of cargo experiments and supplies between the two spacecraft. Long-term American experiments that had been on board Mir were also moved into Discovery. Hatches were closed for undocking at 9:07 a.m. Eastern Daylight Time (EDT) on June 8 and the spacecraft separated at 12:01 p.m. EDT that day.[20][41][42]

Three modules linked in a linear arrangement float in space with the Earth in the background. The top module is a metallic cylinder with a large white circle visible on it and a black cone at either end. The two lower modules are cylindrical and covered in white insulation, and have two blue solar arrays projecting from each. A smaller, brown spacecraft is docked to the lower module.
The International Space Station, Phase Two of the ISS program

Phases Two and Three: ISS (1998–present)

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With the landing of Discovery on June 12, 1998, the Phase One program concluded. Techniques and equipment developed during the program assisted the development of Phase Two: initial assembly of the International Space Station (ISS). The arrival of the Destiny Laboratory Module in 2001 marked the end of Phase Two and the start of Phase Three, the final outfitting of the station, completed in 2012.[43]

In 2015, a reconfiguration of the American segment was completed to allow its docking ports to accommodate NASA-sponsored commercial crew vehicles, that were expected to start visiting the ISS in 2018.[44]

As of June 2015, the ISS has a pressurized volume of 915 cubic metres (32,300 cu ft), and its pressurized modules total 51 metres (167 ft) in length, plus a large truss structure that spans 109 metres (358 ft), making it the largest spacecraft ever assembled.[45] The completed station consists of five laboratories and is able to support six crew members. With over 332 cubic metres (11,700 cu ft) of habitable volume and a mass of 400,000 kilograms (880,000 lb) the completed station is almost twice the size of the combined Shuttle–Mir spacecraft.[45]

Phases Two and Three are intended to continue both international cooperation in space and zero-gravity scientific research, particularly regarding long-duration spaceflight. By spring 2015, Roscosmos, NASA, and the Canadian Space Agency (CSA) have agreed to extend the ISS's mission from 2020 to 2024.[46]

In 2018 that was then extended out to 2030.[47] The results of this research will provide considerable information for long-duration expeditions to the Moon and flights to Mars.[48]

Following the intentional deorbiting of Mir on 23 March 2001, the ISS became the only space station in orbit around Earth.[49] It retained that distinction until the launch of Chinese Tiangong-1 space laboratory on 29 September 2011.[50]

Mir's legacy lives on in the station, bringing together five space agencies in the cause of exploration and allowing those space agencies to prepare for their next leap into space, to the Moon, Mars and beyond.[51]

Complete list of Shuttle–Mir missions

[edit]

Controversy

[edit]
A man holding a piece of hose floats in front of a selection of transient space station hardware. He is wearing a gray-and-yellow plastic mask over his mouth and nose, a pair of goggles above his eyes, and a blue jumpsuit with a name patch on it.
Astronaut Jerry Linenger wearing a respirator mask following the 1997 fire aboard Mir

Safety and scientific return

[edit]

Criticism of the program was primarily concerned with the safety of the aging Mir, particularly following the fire aboard the station and collision with the Progress supply vessel in 1997.[10]

The fire, caused by the malfunction of a backup solid-fuel oxygen generator (SFOG), burned for, according to various sources, between 90 seconds and 14 minutes, and produced large amounts of toxic smoke that filled the station for around 45 minutes. This forced the crew to don respirators, but some of the respirator masks initially worn were broken. Fire extinguishers mounted on the walls of the modules were immovable. The fire occurred during a crew rotation, and as such there were six men aboard the station rather than the usual three. Access to one of the docked Soyuz lifeboats was blocked, which would have prevented escape by half of the crew. A similar incident had occurred on an earlier Mir expedition, although in that case the SFOG burned for only a few seconds.[9][10]

The near-miss and collision incidents presented further safety issues. Both were caused by failure of the same piece of equipment, the TORU manual docking system, which was undergoing tests at the time. The tests were called in order to gauge the performance of long-distance docking in order to enable the cash-strapped Russians to remove the expensive Kurs automatic docking system from the Progress ships.

In the wake of the collision NASA and the Russian Space Agency instigated numerous safety councils who were to determine the cause of the accident. As their investigations progressed, the two space agencies results began moving in different directions. NASA's results blamed the TORU docking system, as it required the astronaut or cosmonaut in charge to dock the Progress without the aide of any sort of telemetry or guidance. However, the Russian Space Agency's results blamed the accident on crew error, accusing their own cosmonaut of miscalculating the distance between the Progress and the space station.[52] The Russian Space Agency's results were heavily criticized, even by their own cosmonaut Tsibliyev, on whom they were placing the blame. During his first press conference following his return to Earth, the cosmonaut expressed his anger and disapproval by declaring, "It has been a long tradition here in Russia to look for scapegoats."[53]

The accidents also added to the increasingly vocal criticism of the aging station's reliability. Astronaut Blaine Hammond claimed that his safety concerns about Mir were ignored by NASA officials, and that records of safety meetings "disappeared from a locked vault".[54] Mir was originally designed to fly for five years but eventually flew for three times that length of time. During Phase One and afterward, the station was showing her age—constant computer crashes, loss of power, uncontrolled tumbles through space and leaking pipes were an ever-present concern for crews. Various breakdowns of Mir's Elektron oxygen-generating system were also a concern. These breakdowns led crews to become increasingly reliant on the SFOG systems that caused the fire in 1997. SFOG systems continue to be a problem aboard the ISS.[9]

Another issue of controversy was the scale of its actual scientific return, particularly following the loss of the Spektr science module. Astronauts, managers and various members of the press all complained that the benefits of the program were outweighed by the risks associated with it, especially considering the fact that most of the US science experiments had been contained within the holed module. As such, a large amount of American research was inaccessible, reducing the science that could be performed.[55] The safety issues caused NASA to reconsider the future of the program at various times. The agency eventually decided to continue and came under fire from various areas of the press regarding that decision.[56]

Attitudes

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Attitudes of the Russian space program and NASA towards Phase One were also of concern to the astronauts involved. Because of Russia's financial issues, many workers at the TsUP felt that the mission hardware and continuation of Mir was more important than the lives of the cosmonauts aboard the station. As such the program was run very differently compared to American programs: cosmonauts had their days being planned for them to the minute, actions (such as docking) which would be performed manually by shuttle pilots were all carried out automatically, and cosmonauts had their pay docked if they made any errors during their flights. Americans learned aboard Skylab and earlier space missions that this level of control was not productive and had since made mission plans more flexible. The Russians, however, would not budge, and many felt that significant work time was lost because of this.[9][57]

Following the two accidents in 1997, astronaut Jerry Linenger felt that the Russian authorities attempted a cover-up to downplay the significance of the incidents, fearing that the Americans would back out of the partnership. A large part of this "cover-up" was the seeming impression that the American astronauts were not in fact "partners" aboard the station, but were instead "guests". NASA staff did not find out for several hours about the fire and collision and found themselves kept out of decision-making processes. NASA became more involved when Russian mission controllers intended to place blame for the accident entirely on Vasily Tsibliyev. It was only after the application of significant pressure from NASA that this stance was changed.[9][10]

At various times during the program, NASA managers and personnel found themselves limited in terms of resources and manpower, particularly as Phase Two geared up, and had a hard time getting anywhere with NASA administration. One particular area of contention was with crew assignments to missions. Many astronauts allege that the method of selection prevented the most skilled people from performing roles they were best-suited for.[9][10][58]

Finances

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Since the breakup of the Soviet Union a few years earlier, the Russian economy had been slowly collapsing and the budget for space exploration was reduced by around 80%. Before and after Phase One, a great deal of Russia's space finances came from flights of astronauts from Europe and other countries, with one Japanese TV station paying $9.5 million to have one of their reporters, Toyohiro Akiyama, flown aboard Mir.[9] By the start of Phase One, cosmonauts regularly found their missions extended to save money on launchers, the six-yearly flights of the Progress had been reduced to three, and there was a distinct possibility of Mir being sold for around $500 million.[9]

Critics argued that the $325 million contract NASA had with Russia was the only thing keeping the Russian space program alive, and only the Space Shuttle was keeping Mir aloft. NASA also had to pay hefty fees for training manuals and equipment used by astronauts training at Star City.[10] Problems came to a head when ABC's Nightline revealed that there was a distinct possibility of embezzlement of American finances by the Russian authorities in order to build a suite of new cosmonaut houses in Moscow, or else that the building projects were being funded by the Russian Mafia. NASA administrator Goldin was invited onto Nightline to defend the homes but he refused to comment. NASA's office for external affairs was quoted as saying, "What Russia does with its own money is their business."[9][59]

See also

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References

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Public Domain This article incorporates public domain material from websites or documents of the National Aeronautics and Space Administration.

  1. ^ NASA.gov . Retrieved 27 November 2020
  2. ^ s:Mir Hardware Heritage/Part 2 - Almaz, Salyut, and Mir#2.1.6 Shuttle-Salyut (1973-1978; 1980s)
  3. ^ a b c d e f g h i David Harland (November 30, 2004). The Story of Space Station Mir. New York: Springer-Verlag New York Inc. ISBN 978-0-387-23011-5.
  4. ^ Al-Khatib, Talal (22 February 2016). "30 Years Later: The Legacy of the Mir Space Station". Space.com. Archived from the original on 16 May 2023. Retrieved 23 May 2023.
  5. ^ Donna Heivilin (June 21, 1994). "Space Station: Impact of the Expanded Russian Role on Funding and Research" (PDF). Government Accountability Office. Archived (PDF) from the original on July 21, 2011. Retrieved November 3, 2006.
  6. ^ Kim Dismukes (April 4, 2004). "Shuttle–Mir History/Background/How "Phase 1" Started". NASA. Archived from the original on November 16, 2001. Retrieved April 12, 2007.
  7. ^ Kim Dismukes (April 4, 2004). "Shuttle–Mir History/Welcome/Goals". NASA. Archived from the original on November 13, 2001. Retrieved April 12, 2007.
  8. ^ George C. Nield & Pavel Mikhailovich Vorobiev (January 1999). Phase One Program Joint Report (PDF) (Report). NASA. Archived from the original (PDF) on 2004-11-17. Retrieved March 30, 2007.
  9. ^ a b c d e f g h i j k l m Bryan Burrough (January 7, 1998). Dragonfly: NASA and the Crisis Aboard Mir. London, UK: Fourth Estate Ltd. ISBN 978-1-84115-087-1. ASIN 1841150878.
  10. ^ a b c d e f g h i j Linenger, Jerry (January 1, 2001). Off the Planet: Surviving Five Perilous Months Aboard the Space Station Mir. New York, USA: McGraw-Hill. ISBN 978-0-07-137230-5. ASIN 007137230X.
  11. ^ David S. F. Portree (March 1995). "Mir Hardware Heritage" (PDF). NASA Sti/Recon Technical Report N. 95: 23249. Archived from the original (PDF) on 7 September 2009. Retrieved March 30, 2007.
  12. ^ Launius, Roger D. "Space Task Group Report, 1969". NASA. Archived from the original on 2018-12-24. Retrieved 2019-08-15.
  13. ^ Malik, Tarik (July 21, 2011). "NASA's Space Shuttle By the Numbers: 30 Years of a Spaceflight Icon". Space.com. Archived from the original on May 23, 2019. Retrieved June 18, 2014.
  14. ^ Jim Wilson (March 5, 2006). "Shuttle Basics". NASA. Archived from the original on October 3, 2009. Retrieved September 21, 2009.
  15. ^ David M. Harland (July 5, 2004). The Story of the Space Shuttle. Springer-Praxis. ISBN 978-1-85233-793-3.
  16. ^ a b Sue McDonald (December 1998). Mir Mission Chronicle (PDF) (Report). NASA. Archived from the original (PDF) on May 31, 2010. Retrieved March 30, 2007.
  17. ^ Kim Dismukes (April 4, 2004). "Shuttle–Mir History/Spacecraft/Space Shuttle Orbiter". NASA. Archived from the original on November 10, 2001. Retrieved March 30, 2007.
  18. ^ Justin Ray (April 14, 2000). "Columbia Weight Loss Plan". Spaceflight Now. Archived from the original on June 7, 2011. Retrieved October 29, 2009.
  19. ^ William Harwood (February 4, 1994). "Space Shuttle Launch Begins Era of US-Russian Cooperation". Washington Post. Retrieved March 9, 2007 from NewsBank. p. a3.
  20. ^ a b c d e f g h i j k l m n o "Shuttle–Mir History/Shuttle Flights and Mir Increments". NASA. Archived from the original on November 11, 2001. Retrieved March 30, 2007.
  21. ^ Jim Dumoulin (June 29, 2001). "STS-60 Mission Summary". NASA. Archived from the original on March 3, 2016. Retrieved March 30, 2007.
  22. ^ Jim Dumoulin (June 29, 2001). "STS-63 Mission Summary". NASA. Archived from the original on March 20, 2009. Retrieved March 30, 2007.
  23. ^ Kathy Sawyer (January 29, 1995). "US & Russia Find Common Ground in Space – Nations Overcome Hurdles in Ambitious Partnership". Washington Post. Retrieved March 9, 2007 from NewsBank. p. a1.
  24. ^ a b List of Mir expeditions
  25. ^ Scott, David; Leonov, Alexei (April 30, 2005). Two Sides of the Moon. Pocket Books. ISBN 978-0-7434-5067-6. ASIN 0743450671.
  26. ^ Jim Dumoulin (June 29, 2001). "STS-71 Mission Summary". NASA. Archived from the original on March 29, 2015. Retrieved March 30, 2007.
  27. ^ Nick Nuttall (June 29, 1995). "Shuttle homes in for Mir docking". The Times. Retrieved March 9, 2007 from NewsBank.
  28. ^ "CSA – STS-74 – Daily Reports". Canadian Space Agency. October 30, 1999. Archived from the original on July 16, 2011. Retrieved September 17, 2009.
  29. ^ Jim Dumoulin (June 29, 2001). "STS-74 Mission Summary". NASA. Archived from the original on December 20, 2016. Retrieved March 30, 2007.
  30. ^ William Harwood (November 15, 1995). "Space Shuttle docks with Mir – Atlantis uses manoeuvres similar to those needed for construction". Washington Post. Retrieved March 9, 2007 from NewsBank. p. a3.
  31. ^ William Harwood (March 28, 1996). "Shuttle becomes hard-hat area; spacewalking astronauts practice tasks necessary to build station". Washington Post. Retrieved March 9, 2007 from NewsBank. p. a3.
  32. ^ Jim Dumoulin (June 29, 2001). "STS-76 Mission Summary". NASA. Archived from the original on August 6, 2013. Retrieved March 30, 2007.
  33. ^ William Harwood (September 20, 1996). "Lucid transfers from Mir to Space Shuttle". Washington Post. Retrieved March 9, 2007 from NewsBank. p. a3.
  34. ^ Jim Dumoulin (June 29, 2001). "STS-79 Mission Summary". NASA. Archived from the original on May 18, 2007. Retrieved March 30, 2007.
  35. ^ a b Jim Dumoulin (June 29, 2001). "STS-81 Mission Summary". NASA. Archived from the original on May 20, 2007. Retrieved March 30, 2007.
  36. ^ Jim Dumoulin (June 29, 2001). "STS-84 Mission Summary". NASA. Archived from the original on February 10, 2007. Retrieved March 30, 2007.
  37. ^ David Hoffman (August 22, 1997). "Crucial Mir spacewalk carries high hopes – continued Western support could hinge on mission's success". Washington Post. Retrieved March 9, 2007 from NewsBank. p. a1.
  38. ^ Jim Dumoulin (June 29, 2001). "STS-86 Mission Summary". NASA. Archived from the original on March 3, 2016. Retrieved March 30, 2007.
  39. ^ Jim Dumoulin (June 29, 2001). "STS-89 Mission Summary". NASA. Archived from the original on March 4, 2016. Retrieved March 30, 2007.
  40. ^ Thomas, Andrew (September 2001). "Letters from the Outpost". NASA. Archived from the original on October 8, 2006. Retrieved April 15, 2007.
  41. ^ Jim Dumoulin (June 29, 2001). "STS-91 Mission Summary". NASA. Archived from the original on March 4, 2016. Retrieved March 30, 2007.
  42. ^ William Harwood (June 13, 1998). "Final American returns from Mir". Washington Post. Retrieved March 9, 2007 from NewsBank. p. a12.
  43. ^ Esquivel, Gerald (23 March 2003). "ISS Phases I, II and III". NASA. Archived from the original on 2007-12-14. Retrieved 2007-06-27.
  44. ^ Harding, Pete (26 May 2015). "ISS relocates PMM in reconfiguration for future crew vehicles". NASA Spaceflight.com. Archived from the original on 1 June 2015. Retrieved 2015-06-13.
  45. ^ a b Garcia, Mark (30 April 2015). "ISS Facts and Figures". International Space Station. NASA. Archived from the original on 3 June 2015. Retrieved 2015-06-13.
  46. ^ Clark, Stephen (24 February 2015). "Russian Space Agency Endorses ISS Until 2024". Spaceflight Now. Archived from the original on 14 June 2015. Retrieved 2015-06-14.
  47. ^ "Senate passes commercial space bill". SpaceNews.com. 2018-12-21. Archived from the original on 2021-09-27. Retrieved 2019-03-26.
  48. ^ Garcia, Mark (30 April 2015). "International Cooperation". International Space Station. NASA. Archived from the original on 28 May 2015. Retrieved 2015-06-13.
  49. ^ Boyle, Alan (23 March 2001). "Russia bids farewell to Mir". NBC News. New York. Archived from the original on 15 June 2015. Retrieved 2015-06-13.
  50. ^ Malik, Tariq (29 September 2011). "China's Tiangong 1 Space Lab: Questions & Answers". Space.com. Archived from the original on 26 September 2015. Retrieved 2015-06-13.
  51. ^ Cabbage, Michael (31 July 2005). "NASA outlines plans for Moon and Mars". Orlando Sentinel. Archived from the original on 12 March 2007. Retrieved 2009-09-17.
  52. ^ Burrough, Bryan (1999). Dragonfly. Fourth Estate.
  53. ^ Specter, Michael (17 August 1997). "Refusing To Play Role Of Mir's Scapegoat, Crew Fights Back". New York Times.
  54. ^ Alan Levin (February 6, 2003). "Some question NASA experts' objectivity". USA Today. Archived from the original on 2011-06-04. Retrieved 2017-08-22.
  55. ^ James Oberg (September 28, 1997). "NASA's 'Can-Do' style is clouding its vision of Mir". Washington Post. Retrieved March 9, 2007 from NewsBank. p. C1.
  56. ^ Mark Prigg (April 20, 1997). "Row between Nasa and the Russian Space Agency – Innovation". The Sunday Times. Retrieved March 9, 2007 from NewsBank. Sport 20.
  57. ^ Leland F. Belew (1977). "9 The Third Manned Period". SP-400 Skylab, Our First Space Station. NASA. Archived from the original on March 16, 2007. Retrieved April 6, 2007.
  58. ^ Ben Evans (2007). Space Shuttle Challenger: Ten Journeys into the Unknown. Warwickshire, United Kingdom: Springer-Praxis. ISBN 978-0-387-46355-1. ASIN 0387463550.
  59. ^ "SpaceViews Update 97 May 15: Policy". Students for the Exploration and Development of Space. May 15, 1997. Archived from the original on March 12, 2005. Retrieved April 5, 2007.
  1. ^ Like the earlier Apollo–Soyuz program, the Russian language version presents its vehicle name first, so the literal translation is ‘program “Mir”–“Shuttle”’
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