Space Station Expedition 21/22
Space Station Expedition 21/22
Space Station Expedition 21/22
www.nasa.gov
TABLE OF CONTENTS
Section Page
MISSION OVERVIEW ............................................................................................................... EXPEDITION 21 & 22 CREW .................................................................................................... EXPEDITION 21/22 MAJOR MILESTONES ............................................................................... EXPEDITION 21/22 SPACEWALKS .......................................................................................... RUSSIAN SOYUZ TMA .............................................................................................................
S O Y U Z B O O ST E R R O CK ET C HA RA C T ER IS T I CS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . P R ELA U N CH C O U N T DO W N T IM EL I N E . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. A S C E NT / I NSE R T IO N TIM EL I N E . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. . . . . . . O R B ITAL I N SER T IO N TO DO C K I N G T IMEL I NE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . K E Y T IM E S FO R EX PED IT IO N 21 /22 I NT E R NA TI O NAL SP A CE S TAT I O N E V ENT S . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . E X P E D IT I ON 20 / SO Y U Z TMA -1 4 L A NDING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SOYUZ TM A- 14 ENT RY TI MEL I NE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. . . . . .
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MINI-RESEARCH MODULE 2 ................................................................................................... INTERNATIONAL SPACE STATION: EXPEDITION 21/22 SCIENCE OVERVIEW ....................... DIGITAL NASA TELEVISION .................................................................................................... EXPEDITION 21/22 PUBLIC AFFAIRS OFFICERS (PAO) CONTACTS .......................................
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Mission Overview
Expeditions 21 and 22
The next set of overlapping crews to live and work aboard the International Space Station will continue its evolution from orbiting outpost to multidisciplinary laboratory, activating recently delivered research facilities, integrating new supply lines and enhancing living conditions. A total of nine long-term residents will span the Expedition 21 and 22 timeframe, welcoming 13 guests. These comings and goings are indicative of the fast-paced traffic pattern that will continue as the space station transitions from construction site to research center. The Expedition 21 and 22 crews will be instrumental in setting up and activating new research facilities, such as the Fluids Integrated Rack and Materials Science Research Rack 1 that were delivered to the station by the STS-128 shuttle mission. Theyll also activate the new Combined Operational Load-Bearing External Resistance Treadmill (COLBERT); unberth the Japanese H-II Transfer Vehicle when its supply mission is complete; and welcome a new Russian docking module, two shuttle crews and a Progress resupply ship. Belgian astronaut Frank De Winne will become the first European Space Agency commander of the station not long after the next crew transport arrives to continue outfitting the station for an expanding research portfolio. De Winne will take over for Commander Gennady Padalka, the Russian cosmonaut who has been station commander for the past six months, when Padalka and NASA astronaut Mike Barratt are ready to return home to Earth in early October. By that time, the next station commander, NASA astronaut Jeff Williams, and Russian flight engineer Max Suraev, will have arrived on the station and joined De Winne, astronaut Nicole Stott, Canadian astronaut Robert Thirsk and Russian flight engineer Roman Romanenko. Those spacefarers will comprise the Expedition 21 crew. Williams and Suraev, along with Canadian spaceflight participant Guy Laliberte, are set for launch to the space station on Sept. 30, 2009, from the Baikonur Cosmodrome in Kazakhstan aboard the Russian Soyuz TMA-16 spacecraft. Williams and Suraev will serve as Expedition 21 flight engineers until DeWinne, Romanenko and Thirsk return to Earth in November and Williams assumes command of the Expedition 22 crew.
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MISSION OVERVIEW
Expedition 21 crew members take a break from training at NASAs Johnson Space Center to pose for a crew portrait. Pictured on the front row are European Space Agency astronaut Frank De Winne (center), commander; NASA astronaut Nicole Stott and Russian cosmonaut Roman Romanenko, both flight engineers. Pictured on the back row (from the left) are Russian cosmonaut Maxim Suraev, NASA astronaut Jeffrey Williams and Canadian Space Agency astronaut Robert Thirsk, all flight engineers.
Expedition 22 crew members from the left (front row) are NASA astronaut Jeffrey Williams, commander; and Russian cosmonaut Oleg Kotov, flight engineer. From the left (back row) are NASA astronaut T.J. Creamer, Russian cosmonaut Maxim Suraev and Japan Aerospace Exploration Agency (JAXA) astronaut Soichi Noguchi, all flight engineers.
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Astronaut Jeffrey Williams (center), Expedition 21 flight engineer and Expedition 22 commander, participates in a 1-G Extravehicular Activity (EVA) training session in the staging area in the Neutral Buoyancy Laboratory (NBL) near NASAs Johnson Space Center. Crew trainer Ernest Bell (left) assists Williams. The first indirect crew exchange of the program will result in Williams and Suraev being together alone for 16 days before the arrival of Russian cosmonaut and Expedition 23 commander Oleg Kotov, NASA astronaut T.J. Creamer and Japanese Aerospace Exploration Agency spaceflight veteran Soichi Noguchi. They are scheduled to launch from Baikonur in December aboard the Soyuz TMA-17 spacecraft. De Winne, Thirsk and Romanenko will depart the station Dec. 1, in their Soyuz 19 spacecraft after 187 days in orbit. Stott will return home aboard the space shuttle Atlantis at the conclusion of the STS-129 mission, the last astronaut expected to use the shuttle for transportation to or from the station.
OCTOBER 2009
MISSION OVERVIEW
Japan Aerospace Exploration Agency (JAXA) astronaut Soichi Noguchi, Expedition 22/23 flight engineer, gets help in the donning of a training version of his Extravehicular Mobility Unit (EMU) spacesuit before being submerged in the waters of the Neutral Buoyancy Laboratory (NBL) near NASAs Johnson Space Center. Williams, 51, a retired U.S. Army colonel from Winter, Wis., is making his third space flight. The West Point graduate began working with NASA in 1987 on assignment from the Army, and was selected as an astronaut in 1996. In May 2000, he served as the flight engineer and lead spacewalker on STS-101. In July 2002, he commanded a nine-day undersea coral reef expedition operating from the National Oceanic and Atmospheric Administrations Aquarius habitat off the coast of Florida. In 2006, he served as Expedition 13 flight engineer aboard the station, spending nearly 183 days in orbit. All totaled, Williams has logged more than 193 days in space, including more than19 hours on three spacewalks. Suraev, 37, a Russian Air Force major, will be making his first space flight, commanding the Soyuz spacecraft for its launch and landing and serving as a station flight engineer. Born in Chelyabinsk, Russia, he graduated with honors from the Kachin Air Force Pilot School in 1994. That same year, he entered the Zhukovski Air Force Academy, from which he also graduated with honors in 1998, as pilotengineer-researcher. At the pilot school he flew L-39 and Su-27 (Flanker) aircraft and has logged around 500 hours of flight time. He was selected as a test-cosmonaut candidate of the Gagarin Cosmonaut Training Center Cosmonaut Office in 1997.
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NASA astronaut T.J. Creamer and Japan Aerospace Exploration Agency (JAXA) astronaut Soichi Noguchi (mostly out of frame), both Expedition 22/23 flight engineers, participate in a training session with the Vestibule Operations Trainer (VOT) in the Space Vehicle Mock-up Facility at NASAs Johnson Space Center. Laliberte, 50, from Qubec City, Canada, is the founder and chief executive officer of the entertainment troupe Cirque de Soleil. He will spend nine days on the station, flying under an agreement between the Russian Federal Space Agency and Space Adventures, Ltd. Kotov, 43, a physician and Russian Air Force colonel, will be making his second spaceflight and serving his second tour aboard the station. Selected as a cosmonaut in 1996, he trained as a cosmonaut researcher for a flight on the Soyuz and as a backup crew member to the Mir-26 mission. A former lead test doctor at Gagarin Cosmonaut Training Center, he served as a flight engineer and Soyuz commander on the Expedition 15 mission in 2007. He will be a flight engineer for Expedition 22, and assume the duties of Expedition 23 commander when Williams departs in March 2010. Creamer, 49, a U.S. Army colonel from Upper Marlboro, Md., will be making his first spaceflight. Assigned to NASAs Johnson Space Center in 1995 as a space shuttle vehicle integration test engineer, he supported eight shuttle missions as a vehicle integration test team lead and specialized in coordinating the information technologies for the Astronaut Office. Selected as an astronaut in 1998, Creamer worked with hardware integration and robotics, and was a support astronaut for Expedition 12.
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MISSION OVERVIEW
European Space Agency (ESA) astronaut Frank De Winne, Expedition 20 flight engineer and Expedition 21 commander, and astronaut Nicole Stott, Expedition 20/21 flight engineer, participate in a HTV berthing robotics operations training session in the Avionics Systems Laboratory at NASAs Johnson Space Center. Noguchi, 49, an aeronautical engineer from Chigasaki, Kanagawa, Japan, will be making his second spaceflight. He was selected as a National Space Development Agency of Japan (NASDA), now JAXA, as an astronaut candidate in 1996 and trained at Johnson Space Center. After completing his astronaut training, he supported development and integration of the stations Japanese Kibo experiment module. Noguchi flew on the STS-114 return-to-flight mission of Discovery in 2005. He has logged nearly 14 days in space, including more than 20 hours of spacewalks to test new procedures for shuttle inspection and repair techniques. The Expedition 21 and 22 crews will work with experiments across a variety of fields, including human life sciences, physical sciences and Earth observation, and conduct technology demonstrations. As with prior expeditions, many experiments are designed to gather information about the effects of long-duration spaceflight on the human body, which will help with planning future exploration missions to the moon and Mars. They also will activate the new COLBERT treadmill for scientific exercise program development and relocate it to the U.S. Tranquility module after its arrival on the shuttle Endeavour in February 2010.
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Padalka and Barratt, joined by Laliberte, will undock and return home to Earth after nine days of handover activities, landing in Kazakhstan on Oct. 11, 2009. The Russian Progress 35 spacecraft will launch from Baikonur on Oct. 15, and arrive at the stations Pirs docking port on Oct. 17, bringing two tons of food, fuel, air and supplies.
The newest Russian module to be added to the station will launch from Baikonur on Nov. 10 atop a Soyuz rocket and dock with to the Zvezda service modules space-facing port on Nov. 12. The shuttle Discovery is scheduled to launch from Kennedy Space Center, Fla., on Nov. 12, and dock with the station on Nov. 14. The STS-129 Utilization and Logistics Flight-3 crew will deliver two Express Logistics Carriers, additional equipment and supplies for use inside the station and conduct three spacewalks. The spacewalkers will install two new materials exposure experiments and a new high-pressure gas tank and position additional external spare parts. Discovery is scheduled to spend seven days at the station before undocking, bringing Stott home after more than 100 days on orbit. The Soyuz 21 craft commanded by Kotov will launch from Baikonur on Dec. 21, and deliver him, Creamer and Noguchi to the station, with docking to the Zarya control modules Earthfacing port. There are no U.S.-based spacewalks currently scheduled for Expedition 21 or 22. However, Suraev and Kotov will don Russian Orlan spacesuits in January for the stations 24th Russian spacewalk. It will be Kotovs third spacewalk and Suraevs first. The focus of the spacewalk will be the Russian segments Mini-Research Module 2 (MRM2), which is scheduled to dock to the station in November and will provide an additional docking port and airlock on the station. Kotov and Suraev will be preparing the module by installing a docking target on its exterior and connecting an antenna that will be used to guide approaching vehicles to the larger antenna system on the Zvezda service module. Theyll also lay cables to connect the module to the stations Ethernet system and install handrails on the hatches that will be used for spacewalks.
Expedition 23 commander, Oleg Kotov; and Japan Aerospace Exploration Agency (JAXA) astronaut Soichi Noguchi (left), Expedition 22/23 flight engineer, participate in a training session in an International Space Station mock-up/trainer in the Space Vehicle Mock-up Facility at NASAs Johnson Space Center.
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MISSION OVERVIEW
Russian cosmonaut Oleg Kotov (foreground), Expedition 22 flight engineer and Expedition 23 commander, along with NASA astronaut T.J. Creamer (center) and Japan Aerospace Exploration Agency (JAXA) astronaut Soichi Noguchi, both Expedition 22/23 flight engineers, participate in a training session in an International Space Station mock-up/trainer in the Space Vehicle Mock-up Facility at NASAs Johnson Space Center. Williams and Suraev are scheduled to relocate their Soyuz to the newly connected MRM2 in January, making room at Zvezdas aft port for the Progress 36 cargo vehicle in February. During three months together as a crew of five, Williams, Suraev, Kotov, Creamer and Noguchi will continue station research and outfitting activities, using Canadarm2 to move Pressurized Mating Adapter 3 from its current location on the port side of the Harmony module to Harmonys Earth-facing common berthing mechanism port, and transferring External Stowage Platform 3 to the opposite side of the stations truss structure. Theyll also complete unloading of the HTV cargo vehicle, load it with refuse, and, using Canadarm2, unberth it from the station and set it adrift so that flight controllers in Japan can command it to reenter the Earths atmosphere and be destroyed. Noguchi and Creamer also will assemble and check out the new JAXA Small Fine Arm (SFA) and install the Kibo airlocks depressurization pump, which will allow experiments to be installed and tested on the Kibo back porch, also known as the Japanese External Facility (JEF). The Small Fine Arm will be used to manipulate experiments on the JEF. Based on robot arm technologies and operation experience from the Manipulator Flight Demonstration conducted on STS-85 in 1997, the SFA includes a 5-foot-long arm with six joints, a tool mechanism and a camera. It was designed so that it could pass through the Kibo airlock for repair and maintenance inside Kibo. In January, one of the stations new commercial resupply rockets, built by Space Exploration Technologies Corp. (SpaceX), will make its first
MISSION OVERVIEW
OCTOBER 2009
demonstration flight. The station crew will not be involved in the mission, but it will mark an important milestone in providing additional supply lines for the station. Also during this period, another Progress resupply exchange is planned. Progress 35 is scheduled to undock from the Pirs docking compartment on Feb. 2. The next Russian cargo shot, Progress 37, will launch from Baikonur and dock with the aft Zvezda port in April. Another shuttle mission in February, STS-130, will deliver the final pressurized U.S. module, Tranquility, and its seven-window cupola. Tranquility will be installed on the newly
vacated port berthing mechanism, and spacewalkers will connects its external utilities over the course of three spacewalks. The shuttle and station crews will work together to integrate regenerative life support systems into the new Tranquility module, which will become the stations utility and exercise room. They will move the Air Revitalization System and its carbon dioxide removal equipment, the Waste and Hygiene Compartment toilet system, the Water Recovery System, the Oxygen Generation System, the Advanced Resistive Exercise Device, the COLBERT treadmill and a crew quarters rack into the newly arrived Tranquility module, freeing up much needed research space in the Destiny Laboratory.
Expedition 21 and 22 crews during Emergency Scene 6 crew training in space station mockups.
OCTOBER 2009
MISSION OVERVIEW
Williams will hand over command of the station to Kotov, and then he and Suraev will depart the station in their Soyuz, with landing in Kazakhstan set for March 18, 2010.
The next expedition crew members are set to arrive at the station in early April.
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Expedition 21 Patch The central element of the patch is inspired by a fractal of six, symbolizing the teamwork of the six-person crew. From the basic element of one person, together six people form a much more complex and multifaceted entity, toward the infinity of the universe. The patch shows children, on Earth in the bright sun, as our future and the reason we explore. The Soyuz and shuttle are the vehicles that enable human space exploration today, while the International Space Station is leading to our next goals, the moon and Mars. The patch shape has six tips, geometrically sound yet reminiscent of a leaf, representing symmetry and ecological harmony, and the six stars in deep space represent the current crew and future exploration crews.
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Expedition 22
Expedition 22 Patch The 22nd Expedition to the International Space Station is dedicated to the final stages of assembly and the transition to full use as an orbiting laboratory. The sun, providing power and life support to the space station, shines through one of the solar arrays as the station orbits above Earth. The oceans and atmosphere, providing life support to Earth, are shown in all their beauty. The moon hovers in the distance as the goal of the next era of exploration. The six stars illustrate the increased capability of the crew complement. In the border are the national flags of the crew members, as well as their surnames in their native languages.
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Frank De Winne European Space Agency (ESA) astronaut Frank De Winne will serve as the International Space Station commander of Expedition 21 after serving as a flight engineer on Expedition 20. He will be the first ESA astronaut to command the station. He served as the flight engineer-1 on Soyuz TMA-15 that launched on May 27, 2009, and has been on board the station since docking on May 29, 2009. Born in Ghent, Belgium, De Winne received a masters degree in telecommunications and civil engineering from the Royal Military Academy, Brussels, in 1984 and, in 1992, graduated from the Empire Test Pilots School in Boscombe Down, England. Since then, De Winne has logged more than 2,300 hours of flight time in several types of high-performance aircraft including Mirage, F16, Jaguar and Tornado. De Winne joined the ESA Astronaut Corps in 2000 and two years later flew on a Soyuz to the space station as part of the Odissea mission. During his nine-day stay, he carried out 23 experiments in the fields of life and physical sciences and education.
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Roman Romanenko Cosmonaut Roman Romanenko, a lieutenant colonel in the Russian Air Force, will serve as a flight engineer on Expedition 21, after serving on Expedition 20. He was the commander of the Soyuz TMA-15 that launched on May 27, 2009. He has been on board the space station since docking on May 29, 2009. Born in the Schelkovo, Moscow Region, Romanenko graduated from pilot school and then served as a second commander in the Air Force. He flew L-39 and Tu-134 aircraft, logging more than 500 hours of flight time. In December 1997, he was selected as a test-cosmonaut candidate of the Gagarin Cosmonaut Training Center Cosmonaut Office. From January 1998 to November 1999, Romanenko completed his basic training course and then qualified as a test-cosmonaut.
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Robert Thirsk Canadian Space Agency (CSA) astronaut Robert Thirsk will serve as a flight engineer on Expedition 21, after serving on Expedition 20. He served as flight engineer-2 on Soyuz TMA-15 that launched on May 27, 2009. He has been on board the space station since docking on May 29, 2009. Born in New Westminster, British Columbia, Thirsk holds engineering degrees from the University of Calgary and MIT, an MBA from MIT, and a medical degree from McGill University. In December 1983, he was selected to the CSA astronaut program and has been involved in various CSA projects including parabolic flight campaigns and mission planning. He served as a crew commander for two space mission simulations: the seven-day CAPSULS mission in 1994 at Defense Research and Development Canada in Toronto; and the 11-day NASA Extreme Environment Mission Operations 7 (NEEMO 7) undersea mission in 2004 at the National Undersea Research Center in Key Largo, Fla. In 1996, Thirsk flew as a payload specialist aboard space shuttle mission STS-78, the Life and Microgravity Spacelab mission. During the 17-day flight aboard shuttle Columbia, he and his six crewmates performed 43 international experiments devoted to the study of life and materials sciences.
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Nicole Stott NASA astronaut Nicole Stott will serve as a flight engineer on Expedition 21 after serving on Expedition 20 since Aug. 30, 2009. She launched on board the space shuttle Discovery on the STS-128 mission on Aug. 28, 2009, and joined the Expedition 20 crew, replacing NASA astronaut Tim Kopra. She will return to Earth on board STS-129 in November 2009. Born in Albany, N.Y., Stott has degrees from Embry-Riddle University and the University of Central Florida. She joined NASAs Kennedy Space Center in 1988 as an operations engineer in the Orbiter Processing Facility before being promoted to vehicle flow director for Endeavour and orbiter test engineer for Columbia. During her last two years at Kennedy, Stott served as the NASA project lead for the space station truss elements under construction at the Boeing Space Station Facility. In 1998, she joined NASAs Johnson Space Center team in Houston as a member of the NASA Aircraft Operations Division, where she served as a flight simulation engineer on the Shuttle Training Aircraft. She was selected as a NASA astronaut in July 2000 and, after initial training, was assigned to the Astronaut Office Station Operations Branch, where she performed crew evaluations of station payloads. She also worked as a support astronaut and capsule communicator for the space station Expedition 10 crew. In April 2006, she was a crew member on the NASA Extreme Environment Mission Operations, or NEEMO, 9 mission. She lived and worked with a six-person crew for 18 days on the Aquarius undersea research habitat.
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Jeffrey Williams NASA astronaut Jeffrey Williams, a retired U.S. Army colonel, will serve as a flight engineer on Expedition 21 and then as commander of Expedition 22. He will serve as flight engineer-1 on Soyuz TMA-16 scheduled to launch on Sept. 30, 2009. He will remain on board the space station after docking on Oct. 2, 2009, until the planned Soyuz landing in Kazakhstan on March 18, 2010. Born in Superior Wis., Williams has degrees from the U.S. Military Academy, the Naval Postgraduate School and the Naval War College. Williams began his NASA experience on an Army assignment at NASAs Johnson Space Center in Houston from 1987 to 1992. He served as a shuttle launch and landing operations engineer, a pilot in the Shuttle Avionics Integration Laboratory and chief of the Operations Development Office, Flight Crew Operations Directorate. Williams attended the U.S. Naval Test Pilot School in 1992 and worked as an experimental test pilot at Edwards Air Force Base in California. He was selected by NASA in the 1996 Astronaut Class. Since his selection, he has completed assignments working on the final assembly of the U.S. Laboratory Module at NASAs Marshall Space Flight Center in Huntsville, Ala., co-chairing the space shuttle cockpit avionics upgrade development, commanding the 9-day NEEMO-3 mission on the Aquarius undersea research habitat, and supporting legislative affairs in Washington, D.C. In May 2000, he served as the flight engineer and lead spacewalker on STS-101 and, in 1996, as the flight engineer for Expedition 13. Williams has logged more than 193 days in space, more than 19 hours of spacewalking time in both U.S. and Russian suits, and more than 2,500 hours in more than 50 different aircraft.
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Maxim Suraev Cosmonaut Maxim Suraev, a colonel in the Russian Air Force, will serve as a flight engineer on Expeditions 21 and 22. He will serve as the commander of Soyuz TMA-16 scheduled to launch on Sept. 30, 2009. He will remain on board the space station after docking on Oct. 2, 2009, until the planned Soyuz landing in Kazakhstan on March 18, 2010. Born in Chelyabinsk, Russia, Suraev graduated with honors from the Kachin Air Force Pilot School as pilot-fighter in 1994. That same year, Suraev entered the Zhukovski Air Force Academy from which he also graduated with honors, in 1998, as pilot-engineer-researcher. At the pilot school he flew L-39 and Su-27 (Flanker) aircraft and has logged about 500 hours of flight time. He was selected as a test-cosmonaut candidate of the Gagarin Cosmonaut Training Center Cosmonaut Office in 1997.
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Oleg Kotov Cosmonaut Oleg Kotov, a colonel in the Russian Air Force, will serve as a flight engineer on Expedition 22 and then as commander of Expedition 23. He will serve as the commander of Soyuz TMA-17 scheduled to launch in December 2009. He will remain on board the space station until a planned Soyuz landing in Kazakhstan in May 2010. Born in Simferopol, Russia, Kotov entered the Kirov Military Medical Academy from which he graduated in 1988. He served at the Gagarin Cosmonaut Training Center where he held the positions of deputy lead test-doctor and lead test-doctor. Kotov was selected as a cosmonaut candidate by GCTC in 1996. From June 1996 to March 1998, he completed a course of basic training for spaceflight. In March 1998, he received a test-cosmonaut qualification. Since July 1998, Kotov has been a cosmonaut-researcher and test-cosmonaut of the GCTC Cosmonaut Office. He began advanced training, in October 1998, for space station flights. During 2001 and 2002 he worked as a CAPCOM for Expeditions 3 and 4. In 2004, he became chief of the CAPCOM Branch in the Cosmonaut Office. In 2007, Kotov served as a flight engineer on Expedition 15 and as the commander of Soyuz TMA-10. He has logged nearly 197 days in space and 5 hours, 25 minutes of spacewalking time.
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Soichi Noguchi Japan Aerospace Exploration Agency astronaut Soichi Noguchi will serve as a flight engineer on Expeditions 22 and 23. He also will serve as flight engineer-1 on Soyuz TMA-17 scheduled to launch in December 2009. He will remain on board the space station until a planned Soyuz landing in Kazakhstan in May 2010. Born in Yokohama, Kanagawa, Japan, Noguchi has degrees from the University of Tokyo and holds a flight instructor certificate as CFII and MEI. He is a member of the Japan Society for Aeronautical and Space Sciences. Noguchi was selected by the National Space Development Agency of Japan (NASDA) in June 1996. Noguchi reported to the Johnson Space Center in August 1996. Having completed two years of training and evaluation, he is qualified for flight assignment as a mission specialist. He participated in the basic training course for Russian human space systems at the Gagarin Cosmonaut Training Center in Russia in 1998. In 2005, Noguchi flew aboard space shuttle Discovery on STS-114, the return-to-flight mission. During that flight, the shuttle docked with the space station, and the crew tested and evaluated new procedures for flight safety and shuttle inspection and repair techniques. Noguchi has logged more than 333 hours in space and more than 20 hours of spacewalking time.
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Timothy Creamer NASA astronaut Timothy TJ Creamer, a colonel in the U.S. Army, will serve as a flight engineer on Expeditions 22 and 23, and as the flight engineer-2 on Soyuz TMA-17 scheduled to launch in December 2009. He will remain on board the space station until a planned Soyuz landing in Kazakhstan in May 2010. Born in Ft. Huachuca, Ariz., Creamer entered the U.S. Army Aviation School in December 1982, and was designated as an Army aviator in August 1983, graduating as the distinguished graduate from his class. He is currently the Armys NASA detachment commander. Creamer has degrees from Loyola College and MIT. Creamer was assigned to NASA at the Johnson Space Center, in July 1995, as a space shuttle vehicle integration test engineer. He has directly supported eight shuttle missions as a vehicle integration test team lead. Creamer was selected as a NASA astronaut in June 1998. Beginning in November 2000, he became the crew support astronaut for the Expedition 3 crew. In March 2002, he headed the Hardware Integration Section of the Space Station Branch, responsible for ensuring all hardware configurations were properly integrated and that all operational aspects of the future station hardware are accounted for. He was the real-time support lead for Expedition 12 for robotics operations on the space station.
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2009:
Sept. 30 Launch of the Expedition 21/22 crew (Williams, Suraev) and Canadian spaceflight participant (Laliberte) from the Baikonur Cosmodrome, Kazakhstan, on Soyuz TMA-16 Expedition 21 docks to the International Space Stations Zvezda Service Module aft port in Soyuz TMA-16 with Canadian space-flight participant Undocking of Expedition 20 crew (Padalka and Barratt) and Canadian spaceflight participant (Laliberte) from Pirs Docking Compartment and landing in Kazakhstan on Soyuz TMA-14; Expedition 21 formally begins with De Winne as ISS Commander Docking of the ISS Progress 35 cargo ship to the Pirs Docking Compartment Undocking of Japanese HTV from the Earth-facing port of the Harmony node Mini-Research Module 2 (MRM2) launches from the Baikonur Cosmodrome, Kazakhstan, on a Russian Soyuz MRM2 docks to the zenith port of the Zvezda Service Modules transfer compartment; launch of Atlantis on the STS-129/ULF3 mission from the Kennedy Space Center Docking of Atlantis to ISS Pressurized Mating Adapter-2 (PMA-2); Stott becomes an STS-129 crew member Undocking of Atlantis from ISS PMA-2 Landing of Atlantis to complete STS-129/ULF3 Undocking of Expedition 20 crew (De Winne, Thirsk, Romanenko) from Zarya module and landing in Kazakhstan on Soyuz TMA-15; Expedition 22 formally begins with Williams as ISS Commander (ISS temporarily occupied by crew of two, Williams and Suraev) Launch of the Expedition 22/23 crew (Kotov, Noguchi, Creamer) from the Baikonur Cosmodrome in Kazakhstan on Soyuz TMA-17 Docking of the Expedition 22/23 crew and Soyuz TMA-17 to the Zarya module; ISS increases in size to five crew members
Oct. 2 Oct. 11
Dec. 7 Dec. 9
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2010:
January January Jan. 5 Jan. 12 Feb. 2 Feb. 3 Feb. 4 Feb. 5 Feb. 6 Feb. 13 Feb. 16 March 18 Russian spacewalk by Suraev and Kotov in Orlan suits to outfit the new MRM2 and retrieve science hardware Relocation of Soyuz TMA-16 to from the Zvezda Service Module aft port to the new MRM2 Relocation of Pressurized Mating Adapter-3 (PMA3) to the Unity nodes Earth-facing port in preparation for the arrival of the Tranquility node Relocation of External Stowage Platform-3 (ESP3) to the S3 truss segment Undocking of ISS Progress 35 from the Pirs Docking Compartment Launch of the ISS Progress 36 cargo ship from the Baikonur Cosmodrome in Kazakshtan Targeted launch of Endeavour on the STS-130/20A mission from the Kennedy Space Center Docking of the ISS Progress 36 cargo ship to the Zvezda Service Modules aft port Docking of Endeavour to ISS PMA-2 Undocking of Endeavour from ISS PMA-2 Landing of Endeavour to complete STS-130/20A Undocking of Expedition 22 crew (Williams, Suraev) from MRM2 and landing in Kazakhstan on Soyuz TMA-16; Expedition 23 formally begins with Kotov as ISS Commander; ISS temporarily manned by crew of three; launch of Discovery on the STS-131/19A mission from the Kennedy Space Center Docking of Discovery to ISS Pressurized Mating Adapter-2 (PMA-2) Undocking of Discovery from ISS PMA-2 Landing of Discovery to complete STS-131/19A
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MISSION MILESTONES
OCTOBER 2009
OCTOBER 2009
SPACEWALKS
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SPACEWALKS
OCTOBER 2009
The Soyuz TMA spacecraft is designed to serve as the ISSs crew return vehicle, acting as a lifeboat in the unlikely event an emergency would require the crew to leave the station. A new Soyuz capsule is normally delivered to the station by a Soyuz crew every six months, replacing an older Soyuz capsule at the ISS. The Soyuz spacecraft is launched to the space station from the Baikonur Cosmodrome in Kazakhstan aboard a Soyuz rocket. It consists of an orbital module, a descent module and an instrumentation/propulsion module.
module after the deorbit maneuver and burns up upon re-entry into the atmosphere.
Descent Module
The descent module is where the cosmonauts and astronauts sit for launch, re-entry and landing. All the necessary controls and displays of the Soyuz are here. The module also contains life support supplies and batteries used during descent, as well as the primary and backup parachutes and landing rockets. It also contains custom-fitted seat liners for each crew member, individually molded to fit each person's body this ensures a tight, comfortable fit when the module lands on the Earth. When crew members are brought to the station aboard the space shuttle, their seat liners are brought with them and transferred to the Soyuz spacecraft as part of crew handover activities. The module has a periscope, which allows the crew to view the docking target on the station or the Earth below. The eight hydrogen peroxide thrusters located on the module are used to control the spacecraft's orientation, or attitude, during the descent until parachute deployment. It also has a guidance, navigation and control system to maneuver the vehicle during the descent phase of the mission.
Orbital Module
This portion of the Soyuz spacecraft is used by the crew while on orbit during free-flight. It has a volume of 6.5 cubic meters (230 cubic feet), with a docking mechanism, hatch and rendezvous antennas located at the front end. The docking mechanism is used to dock with the space station and the hatch allows entry into the station. The rendezvous antennas are used by the automated docking system a radar-based system to maneuver towards the station for docking. There is also a window in the module. The opposite end of the orbital module connects to the descent module via a pressurized hatch. Before returning to Earth, the orbital module separates from the descent
OCTOBER 2009
27
This module weighs 2,900 kilograms (6,393 pounds), with a habitable volume of 4 cubic meters (141 cubic feet). Approximately 50 kilograms (110 pounds) of payload can be returned to Earth in this module and up to 150 kilograms (331 pounds) if only two crew members are present. The Descent Module is the only portion of the Soyuz that survives the return to Earth.
orbital module, the intermediate section of the instrumentation/propulsion module separates from the descent module after the final deorbit maneuver and burns up in atmosphere upon re-entry.
Instrumentation/Propulsion Module
This module contains three compartments: intermediate, instrumentation and propulsion. The intermediate compartment is where the module connects to the descent module. It also contains oxygen storage tanks and the attitude control thrusters, as well as electronics, communications and control equipment. The primary guidance, navigation, control and computer systems of the Soyuz are in the instrumentation compartment, which is a sealed container filled with circulating nitrogen gas to cool the avionics equipment. The propulsion compartment contains the primary thermal control system and the Soyuz radiator, with a cooling area of 8 square meters (86 square feet). The propulsion system, batteries, solar arrays, radiator and structural connection to the Soyuz launch rocket are located in this compartment. The propulsion compartment contains the system that is used to perform any maneuvers while in orbit, including rendezvous and docking with the space station and the deorbit burns necessary to return to Earth. The propellants are nitrogen tetroxide and unsymmetric-dimethylhydrazine. The main propulsion system and the smaller reaction control system, used for attitude changes while in space, share the same propellant tanks. The two Soyuz solar arrays are attached to either side of the rear section of the instrumentation/propulsion module and are linked to rechargeable batteries. Like the
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OCTOBER 2009
cooling system was tested on two Soyuz TM flights. Descent module structural modifications, seats and seat shock absorbers were tested in hangar drop tests. Landing system modifications, including associated software upgrades, were tested in a series of airdrop tests. Additionally, extensive tests of systems and components were conducted on the ground.
Ignition of the first stage boosters and the second stage central core occur simultaneously on the ground. When the boosters have completed their powered flight during ascent, they are separated and the core second stage continues to function. First stage separation occurs when the pre-defined velocity is reached, which is about 118 seconds after liftoff.
Soyuz Launcher
Throughout history, more than 1,500 launches have been made with Soyuz launchers to orbit satellites for telecommunications, Earth observation, weather, and scientific missions, as well as for human flights. The basic Soyuz vehicle is considered a three-stage launcher in Russian terms and is composed of: A lower portion consisting of four boosters (first stage) and a central core (second stage). An upper portion, consisting of the third stage, payload adapter and payload fairing. Liquid oxygen and kerosene are used as propellants in all three Soyuz stages.
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29
Second Stage
An NPO Energomash RD 108 engine powers the Soyuz second stage. This engine has four vernier thrusters, necessary for three-axis flight control after the first stage boosters have separated. An equipment bay located atop the second stage operates during the entire flight of the first and second stages.
plotting is performed for flight following and initial performance assessment. All flight data is analyzed and documented within a few hours after launch.
Third Stage
The third stage is linked to the Soyuz second stage by a latticework structure. When the second stages powered flight is complete, the third stage engine is ignited. Separation occurs by the direct ignition forces of the third stage engine. A single-turbopump RD 0110 engine from KB KhA powers the Soyuz third stage. The third stage engine is fired for about 240 seconds. Cutoff occurs at a calculated velocity. After cutoff and separation, the third stage performs an avoidance maneuver by opening an outgassing valve in the liquid oxygen tank.
Rendezvous to Docking
A Soyuz spacecraft generally takes two days to reach the space station. The rendezvous and docking are both automated, though once the spacecraft is within 150 meters (492 feet) of the station, the Russian Mission Control Center just outside Moscow monitors the approach and docking. The Soyuz crew has the capability to manually intervene or execute these operations.
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OCTOBER 2009
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31
T-
3:15
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OCTOBER 2009
TT-
2:15 1:00
TTTTTT-
Ascent/Insertion Timeline
TT+ T+ T+ T+ T+ :00 1:10 1:58 2:00 2:40 4:58 Lift off Booster velocity is 1,640 ft/sec Stage 1 (strap-on boosters) separation Booster velocity is 4,921 ft/sec Escape tower and launch shroud jettison Core booster separates at 105.65 statute miles Third stage ignites Velocity is 19,685 ft/sec Third stage cut-off Soyuz separates Antennas and solar panels deploy Flight control switches to Mission Control, Korolev
T+ 7:30 T+ 9:00
OCTOBER 2009
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Orbit 2
Orbit 3
Orbit 4
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OCTOBER 2009
FLIGHT DAY 1 OVERVIEW (CONTINUED) Orbit 4 (continued) Crew report on burn performance upon AOS - HM and DM pressure checks read down - Post burn Form 23 (AOS/LOS pad), Form 14 and Globe corrections voiced up - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Manual maneuver to +Y to Sun and initiate a 2 deg/sec yaw rotation. MCS is deactivated after rate is established. External boresight TV camera ops check (while LOS) Meal Last pass on Russian tracking range for Flight Day 1 Report on TV camera test and crew health Sokol suit clean up - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Crew Sleep, off of Russian tracking range - Emergency VHF2 comm available through NASA VHF Network Post sleep activity, report on HM/DM Pressures Form 14 revisions voiced up - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Configuration of RHC-2/THC-2 work station in the HM - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking THC-2 (HM) manual control test - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Lunch - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Terminate +Y solar rotation, reactivate MCS and establish LVLH attitude reference (auto maneuver sequence) RHC-2 (HM) Test - Burn data uplink (TIG, attitude, delta V) - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Auto maneuver to burn attitude (TIG - 8 min) while LOS Rendezvous burn while LOS Manual maneuver to +Y to Sun and initiate a 2 deg/sec yaw rotation. MCS is deactivated after rate is established.
Orbit 5
Orbit 6-12
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35
FLIGHT DAY 2 OVERVIEW (CONTINUED) Orbit 18 (2) Post burn and manual maneuver to +Y Sun report when AOS - HM/DM pressures read down - Post burn Form 23, Form 14 and Form 2 (Globe correction) voiced up - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking CO2 scrubber cartridge change out Free time - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Free time - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Last pass on Russian tracking range for Flight Day 2 Free time - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Crew sleep, off of Russian tracking range - Emergency VHF2 comm available through NASA VHF Network Post sleep activity - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Free time, report on HM/DM pressures - Read up of predicted post burn Form 23 and Form 14 - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Free time, read up of Form 2 Globe Correction, lunch - Uplink of auto rendezvous command timeline - A/G, R/T and Recorded TLM and Display TV downlink - Radar and radio transponder tracking Don Sokol spacesuits, ingress DM, close DM/HM hatch - Active and passive vehicle state vector uplinks - A/G, R/T and Recorded TLM and Display TV downlink - Radio transponder tracking
Orbit 19 (3)
Orbit 30 (14)
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OCTOBER 2009
FLIGHT DAY 3 AUTO RENDEZVOUS SEQUENCE (CONCLUDED) Orbit 32 (16) Terminate +Y solar rotation, reactivate MCS and establish LVLH attitude reference (auto maneuver sequence) Begin auto rendezvous sequence - Crew monitoring of LVLH reference build and auto rendezvous timeline execution - A/G, R/T and Recorded TLM and Display TV downlink - Radio transponder tracking Auto Rendezvous sequence continues, flyaround and station keeping - Crew monitor - Comm relays via SM through Altair established - Form 23 and Form 14 updates - Fly around and station keeping initiated near end of orbit - A/G (gnd stations and Altair), R/T TLM (gnd stations), Display TV downlink (gnd stations and Altair) - Radio transponder tracking Final Approach and docking - Capture to docking sequence complete 20 minutes, typically - Monitor docking interface pressure seal - Transfer to HM, doff Sokol suits - A/G (gnd stations and Altair), R/T TLM (gnd stations), Display TV downlink (gnd stations and Altair) - Radio transponder tracking Station/Soyuz pressure equalization - Report all pressures - Open transfer hatch, ingress station - A/G, R/T and playback telemetry - Radio transponder tracking
Orbit 34 (2)
OCTOBER 2009
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OCTOBER 2009
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Expedition 20/SFP Undocking from Space Station on Soyuz TMA-14 (Pirs Docking Compartment) 8:05 p.m. CT on Saturday, Oct. 10 1:05 GMT on Sunday, Oct. 11 5:05 a.m. Moscow time on Sunday, Oct. 11 7:05 a.m. Kazakhstan time on Sunday, Oct. 11 Expedition 20/SFP Deorbit Burn on Soyuz TMA-14 10:38 p.m. CT on Saturday, Oct. 10 3:38 GMT on Sunday, Oct. 11 7:38 a.m. Moscow time on Sunday, Oct. 11 9:38 a.m. Kazakhstan time on Sunday, Oct. 11 Expedition 20/SFP Landing in Soyuz TMA-14 11:29:52 p.m. CT on Saturday, Oct. 10 4:29:52 GMT on Sunday, Oct. 11 8:29:52 a.m. Moscow time on Sunday, Oct. 11 10:29:52 a.m. Kazakhstan time on Sunday, Oct. 11 (appx. 2:41 after sunrise at the landing site)
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OCTOBER 2009
European Space Agency astronauts Frank De Winne (right), Expedition 20 flight engineer, and Christer Fuglesang, STS-128 mission specialist, prepare to install a new crew quarters compartment in the Kibo laboratory of the International Space Station while space shuttle Discovery remains docked with the station.
After a nine day handover with the newly arrived Expedition 21 crew, Expedition 20 Soyuz Commander Gennady Padalka, NASA Flight Engineer Mike Barratt and Canadian spaceflight participant Guy Laliberte will board their Soyuz TMA-14 capsule for undocking and a one-hour descent back to Earth. Padalka and Barratt will complete a six month mission in orbit, while Laliberte will return after an 11-day flight.
About three hours before undocking, Padalka, Barratt and Laliberte will bid farewell to the new Expedition 21 crew, Commander Frank De Winne and Flight Engineers Jeff Williams, Maxim Suraev, Nicole Stott, Roman Romanenko and Robert Thirsk. Williams and Suraev are launching to the International Space Station from the Baikonur Cosmodrome in Kazakhstan on the Soyuz TMA-16 vehicle. Stott arrived at the station in August on space shuttle Discovery.
OCTOBER 2009
41
Romanenko, Thirsk and De Winne arrived in May on board the Soyuz TMA-15 vehicle. The departing crew will climb into their Soyuz vehicle and close the hatch between Soyuz and the Zarya module. Barratt will be seated in the Soyuz left seat for entry and landing as onboard engineer. Soyuz Commander Padalka will be in the center seat, as he was for launch in March, and Laliberte will occupy the right seat. After activating Soyuz systems and getting approval from flight controllers at the Russian Mission Control Center outside Moscow, Padalka will send commands to open hooks and latches between Soyuz and Zarya. Padalka will fire the Soyuz thrusters to back away from Zarya. Six minutes after undocking, with the Soyuz about 66 feet away from the station, Padalka will conduct a separation maneuver, firing the Soyuz jets for about 15 seconds to begin to depart the vicinity of the complex. About 2.5 hours after undocking, at a distance of about 12 miles from the station, Soyuz computers will initiate a deorbit burn braking maneuver. The 4.5-minute maneuver to slow the spacecraft will enable it to drop out of orbit and begin its reentry to Earth. About 30 minutes later, just above the first traces of the Earths atmosphere, computers will command the pyrotechnic separation of the three modules of the Soyuz vehicle. With the crew strapped in the Descent Module, the uppermost Orbital Module, containing the docking mechanism and rendezvous antennas, and the Instrumentation and Propulsion Module at the rear, which houses the engines and avionics, will separate and burn up in the atmosphere. The Descent Modules computers will orient the capsule with its ablative heat shield pointing forward to repel the buildup of heat as it plunges into the atmosphere. The crew will feel
the first effects of gravity about three minutes after module separation at the point called entry interface, when the module is about 400,000 feet above the Earth. About eight minutes later, at an altitude of about 33,000 feet, traveling at about 722 feet per second, the Soyuz will begin a computercommanded sequence for the deployment of the capsules parachutes. First, two pilot parachutes will be deployed, extracting a larger drogue parachute, which stretches out over an area of 79 square feet. Within 16 seconds, the Soyuz descent will slow to about 262 feet per second. The initiation of the parachute deployment will create a gentle spin for the Soyuz as it dangles underneath the drogue chute, assisting in the capsules stability in the final minutes prior to touchdown. A few minutes before touchdown, the drogue chute will be jettisoned, allowing the main parachute to be deployed. Connected to the Descent Module by two harnesses, the main parachute covers an area of about 3,281 feet. The deployment of the main parachute slows the Descent Module to a velocity of about 23 feet per second. Initially, the Descent Module will hang underneath the main parachute at a 30 degree angle with respect to the horizon for aerodynamic stability. The bottommost harness will be severed a few minutes before landing, allowing the Descent Module to right itself to a vertical position through touchdown. At an altitude of a little more than 16,000 feet, the crew will monitor the jettison of the Descent Modules heat shield, which will be followed by the termination of the aerodynamic spin cycle and the dissipation of any residual propellant from the Soyuz. Computers also will arm the modules seat shock absorbers in preparation for landing.
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OCTOBER 2009
When the capsules heat shield is jettisoned, the Soyuz altimeter is exposed to the surface of the Earth. Signals are bounced to the ground from the Soyuz and reflected back, providing the capsules computers updated information on altitude and rate of descent. At an altitude of about 39 feet, cockpit displays will tell Padalka to prepare for the soft landing engine firing. Just 3 feet above the surface, and just seconds before touchdown, the six solid-propellant engines will be fired in a final braking maneuver. This will enable the Soyuz to settle down to a velocity of about five feet per second and land, completing its mission. As always is the case, teams of Russian engineers, flight surgeons and technicians in fleets of MI-8 helicopters will be poised near the normal and ballistic landing zones, and midway in between, to enact the swift recovery of Barratt, Padalka and Laliberte once the capsule touches down.
A portable medical tent will be set up near the capsule in which the crew can change out of its launch and entry suits. Russian technicians will open the modules hatch and begin to remove the crew members. The crew will be seated in special reclining chairs near the capsule for initial medical tests and to begin readapting to Earths gravity. About two hours after landing, the crew will be assisted to the recovery helicopters for a flight back to a staging site in northern Kazakhstan, where local officials will welcome them. The crew then will board a Russian military plane and be flown to the Chkalovsky Airfield adjacent to the Gagarin Cosmonaut Training Center in Star City, Russia, where their families will meet them. In all, it will take around eight hours between landing and the return to Star City. Assisted by a team of flight surgeons, Barratt and Padalka will undergo planned medical tests and physical rehabilitation. Lalibertes acclimation to Earths gravity will take a much shorter period of time due to the brevity of his flight.
NASA astronauts Rick Sturckow (left), STS-128 commander; Nicole Stott, Expedition 20 flight engineer; and Tim Kopra, STS-128 mission specialist, pose for a photo on the middeck of space shuttle Discovery while docked with the International Space Station.
OCTOBER 2009
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OCTOBER 2009
Deorbit Burn (appx 4:22 in duration, 115.2 m/sec.; Soyuz distance from the Space Station is ~12 kilometers; Undocking Command appx + ~2 hours, 30 mins.) 10:38 p.m. CT on Oct. 10 3:38 GMT on Oct. 11 7:38 a.m. Moscow time on Oct. 11 9:38 a.m. Kazakhstan time on Oct. 11 Separation of Modules (~23 mins. after Deorbit Burn; Undocking Command + ~2 hours, 57 mins.) 11:02 p.m. CT on Oct. 10 4:02 GMT on Oct. 11 8:02 a.m. Moscow time on Oct. 11 10:02 a.m. Kazakhstan time on Oct. 11 Entry Interface (400,000 feet in altitude; 3 mins. after Module Separation; 31 mins. after Deorbit Burn; Undocking Command + ~3 hours) 11:06 p.m. CT on Oct. 10 4:06 GMT on Oct. 11 8:06 a.m. Moscow time on Oct. 11 10:06 a.m. Kazakhstan time on Oct. 11 Command to Open Chutes (8 mins. after Entry Interface; 39 mins. after Deorbit Burn; Undocking Command + ~3 hours, 8 mins.) 11:14 p.m. CT on Oct. 10 4:14 GMT on Oct. 11 8:14 a.m. Moscow time on Oct. 11 10:14 a.m. Kazakhstan time on Oct. 11 Two pilot parachutes are first deployed, the second of which extracts the drogue chute. The drogue chute is then released, measuring 24 square meters, slowing the Soyuz down from a descent rate of 230 meters/second to 80 meters/second.
OCTOBER 2009
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The main parachute is then released, covering an area of 1,000 meters; it slows the Soyuz to a descent rate of 7.2 meters/second; its harnesses first allow the Soyuz to descend at an angle of 30 degrees to expel heat, then shifts the Soyuz to a straight vertical descent. Soft Landing Engine Firing (6 engines fire to slow the Soyuz descent rate to 1.5 meters/second just .8 meter above the ground) Landing appx. 2 seconds Landing (~50 mins. after Deorbit Burn; Undocking Command + ~3 hours, 24 mins.) 11:29:52 p.m. CT on Oct. 10 4:29:52 GMT on Oct. 11 8:29:52 a.m. Moscow time on Oct. 11 10:29:52 a.m. Kazakhstan time on Oct. 11 (~2:41 after sunrise at the landing site).
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OCTOBER 2009
Mini-Research Module 2
The Mini-Research Module 2 (MRM2) is a new Russian module that will arrive at the International Space Station early in the Expedition 21 increment. It is scheduled to be launched Nov. 10 from the Baikonur Cosmodrome, Kazakhstan, on a Russian Soyuz rocket, and will dock to the space-facing port of the Zvezda Service Module two days later. Developed at RSC Energia, MRM2 will double as a new airlock and docking port for arriving Russian vehicles to the space station. The module will increase the number of ports on the Russian segment of the station and enable further development of the Russian program of space station experiments and research. MRM2 will provide a docking target for visual monitoring of automated Soyuz and Progress vehicle dockings and will provide up to 3 cubic meters of pressurized volume for stowing cargo and science hardware. For its flight to the station, MRM2 will deliver up to 1,000 kg (2,204 lb) of cargo in its pressurized compartment. Eight hundred kilograms (1,764 lb) will consist of Russian Orlan space suits and life support equipment.
Launch mass Maximum hull diameter Hull length between docking assembly planes Pressurized volume Habitable volume Number of egress hatches (open inward) Egress hatch diameter
3670 50 kg (8091 110 lb) 2.550 m (8 ft 4 in) 4.049 m (13 ft 3 in) 14.8 m3 (523 ft3) 10.7 m3 (380 ft3) 2 1.000 m (3 ft 3 in)
OCTOBER 2009
MINI-RESEARCH MODULE 2
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External Features
Cargo Boom
EV Hatch
Science Hardware
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MINI-RESEARCH MODULE 2
OCTOBER 2009
Magnetic locks
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MINI-RESEARCH MODULE 2
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Soyuz A R2
Progress
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MINI-RESEARCH MODULE 2
OCTOBER 2009
MRM2
SM
MLM
MRM1
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MINI-RESEARCH MODULE 2
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MINI-RESEARCH MODULE 2
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Expeditions 19 24
165 U.S.O.S.-integrated investigations 104 new investigations 78 International Partner investigations > 400 scientists
Number of Investigations, Expeditions 19 24
19 42
CSA, 5
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OCTOBER 2009
SCIENCE OVERVIEW
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Outside the station, the new Materials International Space Station Experiment, MISSE 7, will be installed by the STS-129 crew of Atlantis in December. MISSE 7 will test space suit materials for use on the lunar surface and materials for the new solar arrays being designed for NASAs Orion spacecraft, evaluating how well they withstand the effects of atomic oxygen, ultraviolet, direct sunlight, radiation, and extremes of heat and cold. The work of more than 400 scientists, this research has been prioritized based on fundamental and applied research needs established by NASA and the international partners the Canadian Space Agency (CSA), the European Space Agency (ESA), the Japan Aerospace Exploration Agency (JAXA) and the Russian Federal Space Agency (RSA). Managing the international laboratorys scientific assets, as well as the time and space required to accommodate experiments and programs, from a host of private, commercial, industry and government agencies nationwide, makes the job of coordinating space station research critical. Teams of controllers and scientists on the ground continuously plan, monitor and remotely operate experiments from control centers around the globe. Controllers staff payload operations centers around the world, effectively providing for researchers and the station crew around the clock, seven days a week. State-of-the-art computers and communications equipment deliver up-to-the-minute reports about experiment facilities and investigations between science outposts across the United States and around the world. The payload operations team also synchronizes the payload time lines among international partners, ensuring the best use of valuable resources and crew time.
The control centers of NASA and its partners are NASA Payload Operations Center, Marshall Space Flight Center in Huntsville, Ala. RSA Center for Control of Spaceflights (TsUP in Russian) in Korolev, Russia JAXA Space Station Integration and Promotion Center (SSIPC) in Tskuba, Japan ESA Columbus Control Center (Col-CC) in Oberpfaffenhofen, Germany CSA Payloads Operations Telesciences Center, St. Hubert, Quebec, Canada
NASAs Payload Operations Center serves as a hub for coordinating much of the work related to delivery of research facilities and experiments to the space station as they are rotated in and out periodically when space shuttles or other vehicles make deliveries and return completed experiments and samples to Earth. The payload operations director leads the POCs main flight control team, known as the "cadre," and approves all science plans in coordination with Mission Control at NASAs Johnson Space Center in Houston, the international partner control centers and the station crew.
On the Internet
For fact sheets, imagery and more on Expedition 21/22 experiments and payload operations, visit
http://www.nasa.gov/mission_pages/station/science/
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SCIENCE OVERVIEW
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ZSR
SE#120 JLP1A1
ZSR
SE#122 JLP1P1
HDP
JLP1F1
HDP
JLP1S1
AVCO
aft JPM1O1 overhead JPM1O2 JPM 103 JPM1O4 SE#360 JPM1A4
ZSR
SE#121 port
HDP
forward
HDP
starboard
DMS -2
SE#352 JPM1A1
JRSR-2
SE#354 JPM 1A2
JRSR-1
SE#353 JPM1A3
ICS / PROX
JPM 1O5
Radial Port
DMS -1
SE#351 JPM1A5 JPM1A6
aft
ZSR
SE#31 JPM1D1
SAIBO
SE#365 JPM1D2
RYUTAI
SE#364 JPM1D3
HDP
JPM1D4
AVCO
JPM1D5
RMS
SE#355 JPM 1D6
deck
ECLSS / TCS-1
SE#356 JPM1F1
EPS-1
SE#358 JPM1F2
CQ -3
SE#62 JPM1F3
MELFI-1
SE#25 JPM1F4
EPS-2
SE#359 JPM1F5
ECLSS / TCS -2
SE#357 JPM1F6
J P M
forward
EXPR-5
SE#23
ITCS
ARS
SE#8 NOD2O 5
W/S
SE#362 NOD2O4 SE#301
EXPR-4
SE#17
ZSR
SE#117
NOD1O 4 overhead
LAB1O6 Z1 Truss
ZSR
DDCU -2
SE#9 LAB1P6
RSR (CHeCS )
SE#155 LAB1P5
LAB1O5
LAB1O4
port
FGB
deck
starboard
N o d e 1
SE#110 NOD1P4
GALLEY (EXPR-6 )
SE#318 LAB1P4
MSRR -1 (ARIS )
SE#22 LAB1P3
LAB1O3
LAB1O2
LAB1O1
EXPR-1
SE#14 LAB1P2
EXPR-2 (ARIS )
SE#15 LAB1P1
ZSR
ZSR
SE#111 NOD1D4
PMA -3
RSR
SE#381 NOD1S4
PMA 3
P M A 2
L A B
TCS
SE#2 LAB1D6
MSS/AV
SE#11 LAB1D5
WRS -2
SE#316 LAB1D4
DDCU -1
SE#7 LAB1D3
WHC
SE#317 LAB1D2 SE#6
OGS
SE#313 LAB1D1 SE#5 LAB1S1
ARS
SE#314 LAB1S6
Avionics-1
SE#4 LAB1S5
WRS -1
SE#315 LAB1S4 SE#370
Window
LAB1S3
Avionics-3 Avionics-2
LAB1S2
P M A 2
N o d e 2
DDCU JEM-1
SE#118 NOD2P5
NOD2P4
CQ-1
SE#60 NOD2D5
DDCU ESA-2
SE#304 NOD2D4
JEM PM
T2
SE#45 NOD2S5
DDCU ESA-1
MPLM
P M A 2
SE#303 NOD2S4
ZSR
SE#116
Air lock
TCS
SE#3
MSS/AV
SE#12
FIR (ARIS )
CIR (PaRIS )
SE#21
MELFI-2
SE#34
TeSS
SE#27
CQ -4
SE#63
DDCU JEM-2
COL
SE#302
forward
AIR1O1 overhead COL1O4 COL1O3 COL1O 2 COL1O1
Stowage
ZSR
ZSR
SE#113 COL1A3
ZSR
SE#126 COL1A2
FSL
SE#412 COL1A1
Subsystem NASA Payload NASA Stowage RWS IRED Rack Pivot Point
aft
deck
forward
A i r l o c k
SE#191 AIR1A1
CA Equip
SE#193 AIR1D1
Stowage
SE#192 AIR1F1
C o l u m b u s
SE#112 COL1A4
HRF-2
SE#417 COL1D4
EPM
SE#413 COL1D3
Bio Lab
SE#414 COL1D2
EXPR-3 (ARIS )
SE#16 COL1D1
ETC
SE#415 COL1F4
System
SE#400 COL1F3
System
SE#400 COL1F2
System
SE#400 COL1F1
Avionics
SE#194
HRF -1
SE#13
AVCO
MSG
SE#18
EDR
SE#411
OCTOBER 2009
SCIENCE OVERVIEW
55
EDR
ESA
Facilities
Columbus
EPM
ESA
Facilities
Columbus
ETC
ESA
Facilities
Columbus
FSL
ESA
Facilities
Columbus
56
SCIENCE OVERVIEW
OCTOBER 2009
Ryutai
JAXA
Facilities
Kibo
Saibo
JAXA
Facilities
Kibo
CIR
NASA
Facilities
Destiny
EMCS
NASA
Facilities
OCTOBER 2009
SCIENCE OVERVIEW
57
EXPRESS Rack-2A
EXpedite the PRocessing of Experiments to Space Station Rack-2 Active Rack Isolation System
NASA
Facilities
Destiny
EXPRESS Rack-3A
EXpedite the PRocessing of Experiments to Space Station Rack-3 Active Rack Isolation System
NASA
Facilities
Columbus
58
SCIENCE OVERVIEW
OCTOBER 2009
EXPRESS Rack-5
NASA
Facilities
Kibo
EXPRESS Rack-6
NASA
Facilities
FIR
NASA
Facilities
Destiny
HRF-1
NASA
Facilities
Columbus
OCTOBER 2009
SCIENCE OVERVIEW
59
MELFI
NASA
Facilities
Kibo
MELFI-2
NASA
Facilities
MSG
NASA
Facilities
Columbus
MSRR
NASA
Facilities
Destiny
60
SCIENCE OVERVIEW
OCTOBER 2009
OCTOBER 2009
SCIENCE OVERVIEW
61
62
Acronym AgCam Title
Agricultural Camera
ARISS
NASA
External
Zag
ESA
Ground
ARIL
RSA
EKE
Assessment of Endurance Capacity by Gas Exchange and Heart Rate Kinetics during Physical Training
ESA
AIS/GATOR
RSA ESA
Bakteriofag
RSA
Study of stability of model closed ecological system and its parts under microgravity conditions, both as microsystem components and as perspective biological systems of space crews life support Biotechnology Effect produced by SFFs on expression of strains producing interleukins 1, 1, "ARIL" Human Research Assessment of Endurance Capacity No Facility and by Gas Exchange and Heart Rate Countermeasures Kinetics during Physical Training Development (EKE) targets the development of a diagnostic tool for the assessment of endurance capacity from respiratory and cardiovascular kinetics in response to changes in exercise intensity. It will also provide data for the development of a physiological model to explore the delay and distortion of muscle VO2 signals during their travel to the lungs Biotechnology Cultivation of E.Coli-protein Caf1 producer in zero-g Technology AIS/GATOR (Automatic Unknown Development Identification System/Grappling Adaptor to On-Orbit Railing) aims to demonstrate the space-based capability of identification of maritime vessels using the Automatic Identification System (AIS). The Grappling Adaptor to On-Orbit Railing (GATOR) demonstrates the onorbit capability of simple hardware designed to attached small passive equipment/payloads externally to the ISS Extravehicular handrails Biotechnology Study of effect produced by space flight factors on bacteriophage
ISS
Destiny
Karsten Strauch, ISS European Space Research and Technology Center, Noordwijk, The Netherlands
External
64
Acronym Bar BIF BCAT-3
RSA
RSA
NASA
BCAT-4
NASA
Complex Analysis Testing of principles and methods Effectiveness for the Space Station leak area Estimation control, selection of the sensor design and configuration Biotechnology Study of effect produced by space flight factors on technological and biomedical characteristics of bifid bacteria Biomedical Study of flight medical information support using onboard information medical system Physical Sciences Binary Colloidal Alloy Test - 3 No Facility in Microgravity (BCAT-3) will allow crews to photograph samples of colloidal particles (tiny nanoscale spheres suspended in liquid) to document liquid/gas phase changes, and the formation of colloidal crystals confined to a surface. Results will help scientists develop fundamental physics concepts previously hindered by the effects of gravity. Data may lead to improvements in supercritical fluids used in rocket propellants and biotechnology applications, and advancements in fiber-optics technology Physical Sciences Binary Colloidal Alloy Test - 4 No Facility in Microgravity (BCAT-4) is a follow-on experiment to BCAT-3. BCAT-4 will study ten colloidal samples. Seven of these samples will determine phase separation rates and add needed points to the phase diagram of a model critical fluid system initially studied in BCAT-3. Three of these samples will use model hardspheres to explore colloidal crystal formation, providing insight into how nature brings order out of disorder
David ISS Weitz, Ph.D. and Peter Lu, Ph.D., Harvard University, Cambridge, MA
Destiny
David Weitz, ISS Ph.D. and Peter Lu, Ph.D., Harvard University, Cambridge, MA; Paul M. Chaikin, Ph.D., Princeton University, Princeton, NJ and New York University, New York, NY
Destiny
Physical Sciences The Binary Colloidal Alloy Test - 5 No Facility in Microgravity (BCAT-5) is a suite of four investigations that will photograph randomized colloidal samples onboard the International Space Station (ISS) to determine their resulting structure over time. The use of EarthKAM software and hardware will allow the scientists to capture the kinetics (evolution) of their samples, as well as the final equilibrium state of each sample
Biodegradatsiya
RSA
Biotechnology
Bioemulsiya (Bioemulsion)
RSA
Biotechnology
Assessment of the initial stages of biodegradation and biodeterioration of the surfaces of structural materials Study and improvement of closedtype autonomous reactor for obtaining biomass of microorganisms and bioactive substance without additional ingredients input and metabolism products removal
66
Acronym Hair
Biorisk
RSA
Biotrack
RSA
Human Spaceflight Hair will study the effects of longNo Facility Technology term exposure to the space Development environment on gene expression and mineral metabolism in human hair. Human hair is one of the most suitable biological specimens for a space experiment since there are no special requirements for handling or for use of hardware. Hair matrix cells actively divide in a hair follicle while these cell divisions sensitively reflect physical conditions. The hair shaft records the information of the astronauts' metabolic conditions. These samples give us useful physiological information to examine the effects of spaceflight on astronauts participating in longduration spaceflight missions. In the experiment, two different analyses will be performed using the ISS crew members' hair: 1) Nucleic Acids (RNA and mitochondrial DNA) and proteins in the hair root and 2) Minerals in the hair shaft Biomedical Study of space flight impact on microorganisms-substrates systems state related to space technique ecological safety and planetary quarantine problem Biotechnology Study of space radiation heavy charged particles fluxes influence on genetic properties of bioactive substances cells-producers
BISE
CSA
CFE-2
NASA
Bodies in the Space Environment No Facility (BISE) will evaluate adaptation to, the effect of, and recovery from long-duration microgravity exposure on the perception of orientation using the OCHART protocol Physical Sciences Capillary Flow Experiment 2 No Facility in Microgravity (CFE-2) is a versatile experiment to study characteristics of low-g capillary flows. CFE-2 is designed to probe capillary phenomena of fundamental and applied importance, such as: capillary flow in complex containers, critical, critical wetting in discontinuous structures and surfaces, and passive gas-liquid phase separators Human Research and Countermeasures Development
Destiny
Destiny
68
Acronym
Integrated Cardiac Atrophy and Cardiovascular Diastolic Dysfunction During and After Long Duration Spaceflight: Functional Consequences for Orthostatic Intolerance, Exercise Capability and Risk for Cardiac Arrhythmias
CCISS
NASA
Cascad (Cascade)
RSA
Cardiac Atrophy and Diastolic Dysfunction During and After Long Duration Spaceflight: Functional Consequences for Orthostatic Intolerance, Exercise Capability and Risk for Cardiac Arrhythmias (Integrated Cardiovascular) will quantify the extent, time course and clinical significance of cardiac atrophy (decrease in the size of the heart muscle) associated with longduration space flight. This experiment will also identify the mechanisms of this atrophy and the functional consequences for crewmembers who will spend extended periods of time in space Human Research Cardiovascular and and Cerebrovascular Control on Return Countermeasures from ISS (CCISS) will study the Development effects of long-duration space flight on crewmembers' heart functions and their blood vessels that supply the brain. Learning more about the cardiovascular and cerebrovascular systems could lead to specific countermeasures that might better protect future space travelers. This experiment is collaborative effort with the Canadian Space Agency Biotechnology Study of various types cells cultivation processes
Richard Lee ISS Hughson, Ph.D., University of Waterloo, Waterloo, Ontario, Canada
Destiny
70
Acronym SWAB
RSA NASA
Contur (Sidebar)
RSA
A Comprehensive Characterization of Microorganisms and Allergens in Spacecraft (SWAB) will use advanced molecular techniques to comprehensively evaluate microbes on board the space station, including pathogens (organisms that may cause disease). It also will track changes in the microbial community as spacecraft visit the station and new station modules are added. This study will allow an assessment of the risk of microbes to the crew and the spacecraft Biotechnology Study of the influence factor space flight on activity ferment Physical Sciences Constrained Vapor Bubble (CVB) in Microgravity consists of a remotely controlled microscope and a small, wickless heat pipe or heat exchanger operating on an evaporation/condensation cycle. The objective is to better understand the physics of evaporation and condensation as they affect heat transfer processes in a heat exchanger designed for cooling critical, high heat output, components in microgravity Technical Studies Development of the methods of management through Internet robot-manipulator on ISS
Peter C. Wayner, Jr., Ph.D., Rensselaer Polytechnic Institute, Troy, New York
ISS
Destiny
DTN
NASA
Technology Development
Crew Earth Observations (CEO) No Facility takes advantage of the crew in space to observe and photograph natural and human-made changes on Earth. The photographs record the Earths surface changes over time, along with dynamic events such as storms, floods, fires and volcanic eruptions. These images provide researchers on Earth with key data to better understand the planet The Delay Tolerant Networking (DTN) will test communication protocols with the Commercial Generic Bioprocessing Apparatus (CGBA) onboard the International Space Station that can be used for exploration. The primary purpose of this activity is to rapidly mature the DTN technology for use in NASAs exploration missions and space communications architecture
ISS
72
Acronym DECLIC
Physical Sciences DEvice for the study of Critical in Microgravity LIquids and Crystallization (DECLIC) is a multi-user facility consisting of three investigations, DECLIC - Alice Like Insert (DECLIC-ALI), DECLIC - High Temperature Insert (DECLIC-HTI) and DECLIC - Directional Solidification Insert (DECLIC-DSI) to study transparent media and their phase transitions in microgravity on board the International Space Station (ISS)
74
Acronym
DOSIS-DOBIES Dose Distribution Inside ISS - Dosimetry for Biological Experiments in Space
Dykhanie
RSA
EDOS
ESA
The Dose Distribution Inside ISS - Dosimetry for Biological Experiments in Space (DOSIS-DOBIES) consist of two investigations. The DOSIS portion of the experiment will provide documentation of the actual nature and distribution of the radiation field inside the spacecraft. Integral measurements of energy, charge and LET spectra of the heavy ion component will be done by the use of different nuclear track detectors. The objective of DOBIES is to develop a standard dosimetric method (as a combination of different techniques) to measure the absorbed doses and equivalent doses in biological samples Biomedical Study of respiration regulation and biomechanics under space flight conditions Human Research Early Detection of Osteoporosis in and Space (EDOS) will test the ability of Countermeasures XtremeCT technology (developed Development by SCANCO Medical) to detect bone architecture changes and provide a better evaluation of the kinetics of bone loss recovery postflight
No Facility
Christian Pre/ Ground Alexandre, M.D., Postflight Universite Jean Monnet, St. Etienne, France
EPO-Demos
NASA
Earth Knowledge Acquired by No Facility Middle School Students (EarthKAM), an education activity, allows middle school students to program a digital camera on board the International Space Station to photograph a variety of geographical targets for study in the classroom. Photos are made available on the world wide web for viewing and study by participating schools around the world. Educators use the images for projects involving Earth Science, geography, physics, and social science Education Payload Operation No Facility Demonstrations (EPO-Demos) are recorded video education demonstrations performed on the International Space Station (ISS) by crewmembers using hardware already onboard the ISS. EPODemos are videotaped, edited, and used to enhance existing NASA education resources and programs for educators and students in grades K-12. EPO-Demos are designed to support the NASA mission to inspire the next generation of explorers
Destiny
76
Acronym Neurospat ERB-2
ESA
VO2Max
Evaluation of Maximal Oxygen Uptake and Submaximal Estimates of VO2max Before, During, and After Long Duration International Space Station Missions
NASA
Erasmus Recording Binocular-2 (ERB-2) is a three-dimensional (3-D) video camera that is used to take images of the environment onboard the International Space Station (ISS). These images are used to create an accurate threedimensional map of the interior of ISS Human Research Evaluation of Maximal Oxygen No Facility and Uptake and Submaximal Estimates Countermeasures of VO2max Before, During, and Development After Long Duration International Space Station Missions (VO2max) will document changes in maximum oxygen uptake for crewmembers onboard the International Space Station (ISS) on long-duration missions, greater than 90 days. This investigation will establish the characteristics of VO2max during flight and assess the validity of the current methods of tracking aerobic capacity change during and following the ISS missions
Technology Development
Columbus
Destiny
Functional Task Functional Task Test: Test Physiological Factors Contributing to Changes in Postflight Functional Performance
NASA
Vascular
CSA
HREP-HICO
HICO and RAIDS Experiment Payload Hyperspectral Imager for the Coastal Ocean
NASA
Physical Sciences Foam Casting and Utilization in in Microgravity Space (FOCUS) will provide nanoparticle stabilized foam generation and bubble nucleation and development in microgravity Human Research Functional Task Test: and Physiological Factors Contributing Countermeasures to Changes in Postflight Functional Development Performance (FTT) tests astronauts on an integrated suite of functional and physiological tests before and after short and long-duration space flight. The study will identify critical mission tasks that may be impacted, map physiological changes to alterations in physical performance and aid in the design of countermeasures that specifically target the physiological systems responsible for impaired functional performance Human Research Health Consequences of Longand Duration Flight (Vascular) will Countermeasures provide an integrated approach to Development gain knowledge concerning the mechanisms responsible for changes that will occur in vascular structure with long-duration space flight and to link this with their functional and health consequences Observing the HICO and RAIDS Experiment Earth and Payload - Hyperspectral Imager for Educational the Coastal Ocean (HREP-HICO) Activities will operate a visible and nearinfrared (VNIR) Maritime Hyperspectral Imaging (MHSI) system, to detect, identify and quantify coastal geophysical features from the International Space Station
No Facility
Richard Lee ISS Hughson, Ph.D., University of Waterloo, Waterloo, Ontario, Canada
Columbus
No Facility
External
78
Acronym JAXA-PCG
HREP-RAIDS HICO and RAIDS Experiment Payload Remote Atmospheric and Ionospheric Detection System
JAXA
Identifikatsiya
RSA
Impulse (ulse)
RSA
The HICO and RAIDS Experiment No Facility Payload - Remote Atmospheric and Ionospheric Detection System (HREP-RAIDS) experiment will provide atmospheric scientists with a complete description of the major constituents of the thermosphere (layer of the Earths atmosphere) and ionosphere (uppermost layer of the Earths atmosphere), global electron density profiles at altitudes between 100 - 350 kilometers Applied Research JAXA PCG seeks to grow crystals Ryutai of biological macromolecules by the counter diffusion technique. The main scientific objective of the JAXA PCG experiment is to produce fine-quality protein crystals in microgravity.The crystals will be grown in the JAXA PCG Canister using the Protein Crystallization Research Facility (PCRF) in the RYUTAI rack. The space-grown crystals will be applied to structural biology and pharmaceutical activities.This experiment is a JAXA-ROSCOSMOS science collaboration. JAXA is performing the onboard experiments, including samples from the Russian research group, and OSCOSMOS is operating the launch and retrieval Technical Studies Identification of disturbance sources when the microgravity conditions on the ISS are disrupted Geophysical Ionospheric sounding by pulsed plasma sources
ISS
Kibo
InSPACE-3
NASA
Izgib
RSA
Rad Silk will examine the effects of space radiation and microgravity on silkworm eggs. The silkworm egg is assumed to have a highly sensitive stage during radiation exposure after diapause, since white spots are observed on silkworm caterpillars when exposed to radiation during their egg stages. The eggs will be placed in egg cases. After the launch, at 4C (39.2F), the eggs in the egg cases will be kept cool in the MELFI at 2C (35.6F) for diapause. Before returning to the ground, the eggs will be incubated at 20C (68F) for 6 days using the CBEF, then stored in the MELFI at 2C (35.6F). Some eggs will be frozen at -95C (-139F). As the control sample, one egg case will remain at 2C (35.6F) without incubation. On the ground, the returned eggs will be germinated, and the effects of radiation will be analyzed with a mutation assay, a genetic assay, and biochemical assays Physical Sciences Investigating the Structure of in Microgravity Paramagnetic Aggregates from Colloidal Emulsions - 3 (InSPACE-3) will study the particle dynamics of magnetorheological fluids (fluids that change properties in response to magnetic fields) that can be used to improve or develop new brake systems and robotics Technical Studies Study of the relationship between the onboard systems operating modes and ISS flight conditions
ISS
Columbus
80
Acronym
Dewey's Forest Japan Aerospace Exploration Agency - Education Payload Observation "Dewey's Forest"
Konyugatsiya (Conjugation)
RSA
Kristallizator (Crystallizer)
RSA
RSA ESA
Dewey's Forest is intended to show No Facility how gravity controls the law of nature and influences our way of thinking. After cultivating four Plant Units (Seiryu, Byakko, Suzaku, and Genbu) for 2 months, crew members create a garden and talk about it while taking video. This is a catalyst to rediscover the relationship between plants and humankind, and the history of gardening and nature Biotechnology Working through the process of genetic material transmission using bacteria conjugation method Technology & Biological macromolecules Material Science crystallization and obtaining biocrystal films under microgravity conditions Biotechnology Effect produced by space flight factors on Laktolen producing strain Lessons from Space (LES) are Observing the No Facility Earth and educational activities that will demonstrate basic principles of Educational Activities science, mathematics, technology, engineering and geography. These activities are videotaped and then used in classrooms across Europe
ISS
Columbus
Space Seed will investigate the role Saibo of gravity in regulating the developmental processes of higher plants, using Arabidopsis thaliana, also known as Arabidopsis or thale cress. The seeds will be planted in the plant experiment sample chambers in the Plant Experiment Unit (PEU) before launch. On orbit, the plants in the eight PEUs will be incubated in the Cell Biology Experiment Facility (CBEF) in the SAIBO rack and will be observed using the PEU CCD camera. After about 30 days of incubation, half of the germinated samples (stems, leaves, and roots) will be harvested, fixed, and stored in the Minus Eighty-degree Laboratory Freezer for the ISS (MELFI) at 2C (35.6F) and -95C (-139F). A quarter of the other half will be harvested after an additional 30 days of incubation, then fixed and refrigerated in the MELFI. The rest of the samples, including seeds produced in microgravity, will also be refrigerated. All stored samples will be returned to the ground to be analyzed morphologically and genetically
82
Acronym Card MISSE-7
NASA
Technology Development
No Facility
External
MSL-CETSOL Materials Science and MICAST Laboratory Columnar-toEquiaxed Transition in Solidification Processing and Microstructure Formation in Casting of Technical Alloys under Diffusive and Magnetically Controlled Convective Conditions
Matryeshka-R
RSA
MAUI
NASA
Physical Sciences The Materials Science Laboratory in Microgravity Columnar-to-Equiaxed Transition in Solidification Processing and Microstructure Formation in Casting of Technical Alloys under Diffusive and Magnetically Controlled Convective Conditions (MSLCETSOL and MICAST) are two investigations that support research into metallurgical solidification, semiconductor crystal growth (Bridgman and zone melting), and measurement of thermo-physical properties of materials. This is a cooperative investigation with the European Space Agency (ESA) and National Aeronautics and Space Administration (NASA) for accommodation and operation aboard the International Space Station (ISS) Biomedical Study of radiation environment dynamics along the ISS RS flight path and in ISS compartments, and dose accumulation in anthropomorphous phantom, located inside and outside ISS Technology Maui Analysis of Upper No Facility Development Atmospheric Injections (MAUI) will observe the Space Shuttle engine exhaust plumes from the Maui Space Surveillance Site in Hawaii. The observations will occur when the Space Shuttle fires its engines at night or twilight. A telescope and all-sky imagers will take images and data while the Space Shuttle flies over the Maui site. The images will be analyzed to better understand the interaction between the spacecraft plume and the upper atmosphere of Earth
Shuttle
84
Acronym 3D-Space
MDS
NASA
The purpose of the Mental Representation of Spatial Cues During Space Flight (3D-Space) experiment is to investigate the effects of exposure to microgravity on the mental representation of spatial cues by astronauts during and after space flight. The absence of the gravitational frame of reference during spaceflight could be responsible for disturbances in the mental representation of spatial cues, such as the perception of horizontal and vertical lines, the perception of objects depth, and the perception of targets distance Biological Sciences Mice Drawer System(MDS) is an in Microgravity Italian Space Agency investigation that will use a validated mouse model to investigate the genetic mechanisms underlying bone mass loss in microgravity. Research conducted with the MDS is an analog to the human research program, which has the objective to extend the human presence safely beyond low Earth orbit
Express Rack Mice Drawer ISS System (MDS) is an Italian Space Agency investigation that will use a validated mouse model to investigate the genetic mechanisms underlying bone mass loss in microgravity. Research conducted with the MDS is an analog to the human research program, which has the objective to extend the human presence safely beyond low Earth orbit
Kibo
MAMS/SAMS-II Microgravity Acceleration Measurement System (MAMS) and Space Acceleration Measurement System-II (SAMS-II)
MAXI
JAXA
External
86
Acronym MDCA-FLEX
MDCA-FLEX-2 Multi-User Droplet Combustion Apparatus - Flame Extinguishment and Fundamental Studies in Droplet Combustion in Microgravity - 2
NASA
Technology Development
Forman A. ISS Williams, Ph.D., University of California, San Diego, San Diego, CA
Destiny
Human Spaceflight Myco1 will investigate and evaluate No Facility Technology the risk of inhalation and adhesion Development of microorganisms to astronauts who are exposed to ambient air on board the ISS during long-duration missions. The ultimate goal of this experiment is to develop medically effective countermeasures to protect ISS crew members living in a closed environment of microgravity against the living environmental risks caused by microorganisms. Normal human flora is thought to be strongly affected by the living environment. The environment on board the ISS would progressively be contaminated by microorganisms since various microorganisms are brought up to the station along with commodities and or crew members themselves. Some of them are possible allergens in our living environment. To mitigate the risk of microbial contamination on board, it is necessary to take some countermeasures against microbial contaminations
88
Acronym Repositiory
NLP-Cells-2
NASA
NLP-Cells-3
NASA
The National Aeronautics and Space Administration Biological Specimen Repository (Repository) is a storage bank that is used to maintain biological specimens over extended periods of time and under well-controlled conditions. Biological samples from the International Space Station (ISS), including blood and urine, will be collected, processed and archived during the preflight, inflight and postflight phases of ISS missions. This investigation has been developed to archive biosamples for use as a resource for future space flight related research Biological Sciences National Lab Pathfinder-Cells-2 in Microgravity (NLP-Cells-2) experiment assesses the effects of space flight on the virulence and gene expression of specific virulence factors of S. pneumonia Biological Sciences National Lab Pathfinder-Cells-3 in Microgravity (NLP-Cells-3) experiment examines the effects of space flight on normal cellular replication and differentiation
David W. Niesel, Sortie Ph.D., University of Texas Medical Branch at Galveston, Galveston, TX Sortie
NASA
Immuno
Neuroendocrine and Immune Responses in Humans During and After Long Term Stay at ISS
ESA
Biological Sciences National Lab Pathfinder in Microgravity Vaccine 6 (NLP-Vaccine-6) is part of a suite of investigations serving as a pathfinder for the use of the International Space Station as a National Laboratory after ISS assembly is complete. It contains several different pathogenic (disease causing) organisms. This research is investigating the use of space flight to develop potential vaccines for the prevention of different infections caused by these pathogens on Earth and in microgravity Biological Sciences National Lab Pathfinder in Microgravity Vaccine 7 (NLP-Vaccine-7) is part of a suite of investigations serving as a pathfinder for the use of the International Space Station as a National Laboratory after ISS assembly is complete. It contains several different pathogenic (disease causing) organisms. This research is investigating the use of space flight to develop potential vaccines for the prevention of different infections caused by these pathogens on Earth and in microgravity Human Research Neuroendocrine and Immune and Responses in Humans During and Countermeasures After Long Term Stay at ISS Development (Immuno) will provide an understanding for the development of pharmacological tools to counter unwanted immunological side effects during long-duration missions in space
GAP
Timothy Sortie Hammond, M.B.B.S., Durham Veterans Affairs Medical Center, Durham, NC
Shuttle
Columbus
90
Acronym Nutrition
OChB
RSA
Otolith
ESA
Nutritional Status Assessment (Nutrition) is the most comprehensive inflight study done by NASA to date of human physiologic changes during longduration space flight; this includes measures of bone metabolism, oxidative damage, nutritional assessments, and hormonal changes. This study will impact both the definition of nutritional requirements and development of food systems for future space exploration missions to the Moon and Mars. This experiment will also help to understand the impact of countermeasures (exercise and pharmaceuticals) on nutritional status and nutrient requirements for astronauts Biotechnology Effect produced by SFFs on strain producing superoxidodismutase (SOD) Human Research Otolith Assessment During and Postflight Re-adaptation (Otolith) Countermeasures will assess otolith (small bones of Development the inner ear) function in crewmembers preflight and postflight
No Facility
Andrew H. Pre/ Ground Clarke, Ph.D., Postflight Charite Medical School, Berlin, Germany
Pilot
RSA
Plazmida
RSA
Pneumocard
RSA
Poligen
RSA
Human Spaceflight Area PADLES surveys the space No Facility Technology radiation environment inside Kibo Development using the PADLES analysis system and passive and integrating dosimeter developed by JAXA for measuring absorbed dose, LET distributions, and dose equivalents. Ultimate goals of this program are to support risk assessment and dose management for Japanese astronauts, and to update radiation assessment models for human spaceflight in the next generation. There are 17 Area PADLES dosimeters installed in Kibo's Pressurized Module (PM) and Kibo's Experiment Logistics Module-Pressurized Section (ELM-PS). They are replaced during each space station expedition. This series of experiments began from Expedition 17 Biomedical Researching for individual features of state psychophysiological regulation and crewmembers professional activities during long space flights Biomedical Investigation of microgravity effect on the rate of transfer and mobilization of bacteria plasmids Biomedical Study of space flight factors impacts on vegetative regulation of blood circulation, respiration and contractile heart function during long space flights Biomedical Detection of genotypic features (experimental object Drozophila midge), determining individual characteristics of resistance to the long-duration flight factors
92
Acronym
Applied Research Nanoskeleton1 will quantitatively evaluate Saibo gravitational effects on a new nanomaterial during its chemical reaction process. The nanoskeleton, a coined word that is defined as a functional nanoframework, is expected to be a highly functional material because of its high surface area. The high surface area is due to the pore structure and the functionality of framework itself. The TiO2 nanoskeleton, especially, has potential as a high-performance photocatalyst and highly efficient dye-sensitized solar cell. The TiO2 nanoskeleton is synthesized from a mixture of CTAB surfactant solution and TiOSO4-H2SO4 solution at 40C or 3 days under isothermal conditions. The nanoskeleton experiment will be performed using the CBEF in the SAIBO rack. Oil will be used to enlarge the pore size of the honeycomb structure of the TiO2 nanoskeleton so that flotation of the oil can be suppressed in microgravity. All of the experiment samples will be retrieved and evaluated on the ground. The retrieved samples will be evaluated to clarify convective flow, flotation, and sedimentation effects on the sample quality. During the experiment, temperature and downlinked images of the samples will be monitored. The results of this study may enable the synthesizing of nanoskeleton materials on a mass roduction scale, and eventually, commercial realization of nanoskeleton materials as photocatalytic particles and so on. This experiment will be performed under JAXA's ISS applied research center promotion program, which is a joint versity/Industry/Government research project
RAMBO-2
NASA
Technology Development
Rasteniya
RSA
Biomedical
Relaksatsiya
RSA
Geophysical
The Psychomotor Vigilance Self No Facility Test on the International Space Station (Reaction Self Test) is a portable 5-minute reaction time task that will allow the crewmembers to monitor the daily effects of fatigue on performance while on board the International Space Station Ram Burn Observations - 2 No Facility (RAMBO-2) is an experiment in which the Department of Defense uses a satellite to observe space shuttle orbital maneuvering system engine burns. Its purpose is to improve plume models, which predict the direction the plume, or rising column of exhaust, will move as the shuttle maneuvers on orbit. Understanding the direction in which the spacecraft engine plume, or exhaust flows could be significant to the safe arrival and departure of spacecraft on current and future exploration missions Study of the space flight effect on the growth and development of higher plants Study of chemiluminescent chemical reactions and atmospheric light phenomena that occur during high-velocity interaction between the exhaust products from spacecraft propulsion systems and the Earth atmosphere at orbital altitudes and during the entry of space vehicles into the Earth upper atmosphere
Shuttle
94
Acronym CERISE
Rusalka
RSA
SODI-IVIDIL
ESA
CERISE will examine RNA activity in microgravity, and also investigate protein phosphorylation and signal transduction, which are involved in muscle formation, using a model specimen, C. elegans. RNA interference is a useful technique for silencing specific gene expression with sequence homology, which presently applies to not only basic life science study but also several clinical examinations. From the experiment, the first verification of RNA interference activity in space and signal transduction by microgravity will be clarified Study of Earth Testing of the procedure to natural resources determine the carbon dioxide and and ecological methane content in the Earth monitoring atmosphere to understand a role of natural processes in human activity Physical Sciences Selectable Optical Diagnostics in Microgravity Instrument Influence of Vibration on Diffusion of Liquids (SODI-IVIDIL) will study the influence of controlled vibration stimulus (slow shaking) on diffusion between different liquids in absence of convection induced by the gravity field. Such investigation will help scientists to model numerically this physical phenomenon
Valentina ISS Shevtsova, PhD, Microgravity Research Center, University of Brussels, Belgium
Columbus
Physical Sciences The Selectable Optical Diagnostics in Microgravity InstrumentDiffusion and Soret Coefficient (SODI-DSC) experiment will study diffusion in six different liquids over time in the absence of convection induced by the gravity field
SNFM
NASA
Seyener
RSA
SEITE
NASA
Using a commercial software CD No Facility and minimal up-mass, Serial Network Flow Monitor (SNFM) monitors the payload Local Area Network (LAN) to analyze and troubleshoot LAN data traffic. Validating LAN traffic models may allow for faster and more reliable computer networks to sustain systems and science on future space missions Study of Earth Experimental methodses of the natural resources interaction of the crews to cosmic and ecological station with court Fishing in process monitoring of searching for and mastering commercial-productive region of the World ocean Technology Shuttle Exhaust Ion Turbulence No Facility Development Experiments (SEITE) will use space-based sensors to detect the ionospheric turbulence inferred from the radar observations from a previous Space Shuttle Orbital Maneuvering System (OMS) burn experiment using ground-based radar
Technology Development
ISS
Destiny
Shuttle
96
Acronym SIMPLEX Sleep-Short
NASA
Unknown
Charles A. Sortie Czeisler, M.D., Ph.D. and Laura K. Barger, Ph.D., Brigham and Women's Hospital, Harvard Medical School, Boston, MA Charles A. ISS Czeisler, M.D., Ph.D., Brigham and Women's Hospital, Harvard Medical School, Boston, MA
Shuttle
Sleep-Long
NASA
Columbus
RSA
Technical Studies
SolarSOLACES
ESA
Solar
ISS
External
Solar-SOVIM
ESA
Sonokard
RSA
External Space SOLar SPECtral Irradiance Solar Exposure and Sun Measurements (SOLSPEC) will Observation operate at high spectral resolution in the range 180 to 3000 nm, with an accuracy of 2% in ultravaiolet (UV) and 1% in visible and infrared (IR) External Space SOLar Variable and Irradiance Solar Exposure and Sun Monitor (SOVIM) will measure Observation solar spectral irradiance via filter-radiometers in the near-UV (402 nanometers), visible (500 nanometers) and near-IR (862 nanometers) regions, together with the total solar irradiance, using two types of radiometers covering the range from 200 nanometers to 100 micrometers Biomedical Integrated study of physiological functions during sleep period throughout a long space flight
Claus ISS Froehlich, Ph.D., PhysikalischMeteorologisches ObservatoriumWorld Radiation Centre, Davos, Switzerland
External
98
Acronym
Astrophysics/Earth SEDA-AP is an external JEM-EF Observation experiment conducted on the Exposed Facility (EF). SEDA-AP was launched and installed on Kibo's Exposed Facility (EF) during the STS-127 Mission, and it has been collecting space environment data ever since. It consists of common bus equipment, a mast that extends the neutron monitor sensor into space, and seven measurement units that measure space environment data. The measurement units are (1) Neutron Monitor (NEM), (2) Heavy Ion Telescope (HIT), (3) Plasma Monitor (PLAM), (4) Standard Dose Monitor (SDOM), (5) Atomic Oxygen Monitor (AOM), (6) Electronic Device Evaluation Equipment (EDEE), and (7) Micro-Particles Capture (MPAC) and Space Environment Exposure Device (SEED)
100
Acronym
Spinal Elongation
NASA
RSA RSA
Material Science Marangoni UVP is one of JAXA's Ryutai Marangoni experiments performed using the Fluid Physics Experiment Facility (FPEF) in the RYUTAI rack. The operational method is similar to that of the preceding Marangoni experiment: Chaos, Turbulence, and its Transition Process in Marangoni Convection (MEIS). During the experiment, the flow phenomenon will be investigated using a pulsed ultrasonic velocity profiler to obtain the spatiotemporal velocity field inside the fluid column, so as to investigate and clarify the flow transition scheme from laminar to turbulence through chaos. The experiment cell of this experiment will be delivered to the ISS on the HTV-1 Mission scheduled to launch to the ISS in September 2009 Human Research The purpose of the Spinal Unknown and Elongation and its Effects on Countermeasures Seated Height in a Microgravity Development Environment (Spinal Elongation) study is to provide quantitative data as to the amount of change that occurs in the seated height due to spinal elongation in microgravity Technical Studies Studying ISS characteristics as researching environment Biotechnology Reception high-quality crystal squirrel
Shuttle
SVS ()
RSA
Astrophysics/Earth SMILES is an external observatory JEM-EF Observation to be operated on the EF. SMILES will be launched and installed during the HTV-1 Mission and aims at globally mapping stratospheric trace gases, using the most sensitive submillimeter receiver. A Superconductor/Insulator/ Superconductor (SIS) mixer in a dedicated cryostat with a mechanical cooler achieved SMILES's super-high sensitivity. SMILES will observe ozone depletion-related molecules, such as ClO, HCl, HO2, HNO3, BrO, and O3, in the frequency bands of 624.32 to 626.32 GHz and 649.12 to 650.32 GHz. A scanning antenna will cover tangent altitudes from 10 to 60 km every 53 seconds, while tracing the latitudes from 38S to 65N along its orbit. Due to its global coverage capability, SMILES can observe the low- and mid-latitudinal areas, as well as the Arctic peripheral region. SMILES data will enable us to investigate chlorine and bromine chemistry, and will provide a database for ozone variations in time and position around the upper troposphere and lower stratosphere Technology Self-propagating high-temperature &Material Science fusion in space
102
Acronym SPHERES
Tropi-II
NASA
Synchronized Position Hold, No Facility Engage, Reorient, Experimental Satellites (SPHERES) are bowlingball sized spherical satellites. They will be used inside the space station to test a set of well-defined instructions for spacecraft performing autonomous rendezvous and docking maneuvers. Three free-flying spheres will fly within the cabin of the Space Station, performing flight formations. Each satellite is selfcontained with power, propulsion, computers and navigation equipment. The results are important for satellite servicing, vehicle assembly and formation flying spacecraft configurations Biological Sciences The Analysis of a Novel Sensory Express Rack in Microgravity Mechanism in Root Phototropism - II (Tropi-II) investigation will study the effects of various gravity levels on the responses of plants to light. The results of this experiment can lead to information to help in food production during future long-duration space exploration missions
ISS
Columbus
Thermolab
ESA
Tipologia
RSA
Human Spaceflight Biological Rhythms will record Technology 24-hour continuous ECG data of Development ISS crew members using a commercial Holter ECG recorder. The recordings will be performed once pre-flight, three times in-flight and once post-flight. The in-flight data are downlinked to the ground after measurement. Using the data, cardiovascular and autonomic functions are analyzed. The data are also used to evaluate Biological Rhythm fluctuations and heart rest qualities of crew members while they sleep on board the ISS. The results of this experiment will be applied to improving health care technologies for the ISS crew Human Research Thermoregulation in Humans and During Long-term Space Flight Countermeasures (Thermolab) aims to investigate the Development thermoregulatory and cardiovascular adaptations during rest and exercise in the course of a long-term microgravity exposure. It is hypothesized that heat balance, thermoregulation and circadian temperature rhythms are altered in humans during long-term space flights. Since all physiological change factors are particularly cross-linked with each other in view of thermoregulation, an integrative study of the topic under microgravity conditions is mandatory Biomedical Researching for typological features of the activities of the ISS crews as operators activities in long term space flight phases
ISS
Columbus
104
Acronym TAGES
Uragan
RSA
Spin
ESA
Biological Sciences Transgenic Arabidopsis Gene in Microgravity Expression System (TAGES) investigation is one in a pair of investigations that use the Advanced Biological Research System facility. TAGES uses Arabidopsis thaliana, thale cress, with sensor promoter-reporter gene constructs that render the plants as biomonitors (an organism used to determine the quality of the surrounding environment) of their environment using real-time nondestructive Green Fluorescent Protein imagery and traditional postflight analyses Geophysical Experimental verification of the ground and space-based system for predicting natural and manmade disasters, mitigating the damage caused, and facilitating recovery Human Research The Validation of Centrifugation as and a Countermeasure for Otolith Countermeasures Deconditioning During Development Spaceflight (Spin) experiment will investigate the effect of microgravity on otolith-ocular reflexes and autonomic function to correlate the otolith-ocular reflex on orthostatic tolerance. It will also study the effect of microgravity on subjective perception of verticality
No Facility
Integrated Validation of Immune-SDBI Procedures for Monitoring Crew Member Immune Function - Short Duration Biological Investigation
NASA
Unknown
Shuttle
Vektor-T Veterok
RSA RSA
106
Acronym Yeast-B
Vzaimodeistvie (Interaction) Yeast In No Gravity: The Influence of Microgravity on Cellular Adhesion, Biofilm Formation and Invasive Growth in the Model Eukaryote Saccharomyces cerevisiae - B
RSA
ESA
RSA CSA
Seismic effects monitoring. Researching high-energy particles streams in near-Earth space environment Biomedical Monitoring of the group crew activities under space flight conditions Biological Sciences Yeast In No Gravity: The Influence in Microgravity of Microgravity on Cellular Adhesion, Biofilm Formation and Invasive Growth in the Model Eukaryote Saccharomyces cerevisiae - B (Yeast-B) examines the affect of microgravity on specific proteins of yeast cells (Saccharomyces cerevisiae). This two part investigation uses two different types of cultures, liquid and solid. The objective of this investigation is to provide scientists with data on the impact of microgravity on organized cell structures Biotechnology Study of the possibility to increase the ginseng biological activity Biological Sciences The Cambium investigation is one in Microgravity in a pair of investigations which utilizes the Advanced Biological Research System (ABRS). Cambium seeks definitive evidence that gravity has a direct effect on cambial cells (cells located under the inner bark where secondary growth occurs) in willow, Salix babylonica
BioLab
Columbus
Rodney ISS Savidge, Ph.D., Professor of Tree Physiology and Biochemistry, Faculty of Forestry and Environmental Management, University of New Brunswick, Fredericton, NB, Canada
Destiny
Foam-Stability examines the No Facility characteristics and stability of foam under microgravity conditions
RSA
RSA
RSA
Complex Analysis Effectiveness Estimation Complex Analysis Effectiveness Estimation Complex Analysis Effectiveness Estimation
RSA
RSA
RSA RSA
Experimental researching of ISS RS resources estimating for ecological investigation of areas Study of plasma environment on ISS external surface by optical radiation characteristics Study of microdestruction processes in the ISS habitation modules under the long-term manned flight conditions Complex Analysis Study of the plasma-dust crystals Effectiveness and fluids under microgravity Estimation Complex Analysis Study of reflection characteristics of Effectiveness spacecraft plasma environment Estimation with onboard engines activated Study of cosmic Study of fast and thermal neutrons rays fluxes Space education Scientific-educational demonstration of physical laws and phenomena in microgravity conditions: - operation of basic physical motion laws in weightlessness including the effect of reactive and gyroscopic forces on a solid body of revolution; - diffusion processes and the effect of the liquid surface tension, gas bubbles aggregation during the phase separation of gas-liquid fine-disperser medium
108
Acronym
RSA
Space education Spacecraft and up-to-date technologies for personal communications Commercial Exposure of material samples in open space conditions to study the effect of ultraviolet radiation on them
Internet Information
Information is available through several sources on the Internet. The primary source for mission information is the NASA Human Space Flight Web, part of the World Wide Web. This site contains information on the crew and its mission and will be updated regularly with status reports, photos and video clips throughout the flight. The NASA Shuttle Webs address is: http://spaceflight.nasa.gov General information on NASA and its programs is available through the NASA Home Page and the NASA Public Affairs Home Page: http://www.nasa.gov or http://www.nasa.gov/newsinfo/ index.html
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NASA TELEVISION
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NASA TELEVISION
OCTOBER 2009
202-358-1100
202-358-1100
202-358-1100
Research in Space
202-358-0668
Research in Space
202-358-1756
Astronauts/Mission Operations
281-483-5111
Mission Operations
281-483-5111
Mission Operations
281-483-5111
OCTOBER 2009
PAO CONTACTS
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Kelly Humphries NASA Johnson Space Center Houston kelly.o.humphries@nasa.gov Nicole Cloutier-Lemasters NASA Johnson Space Center Houston nicole.cloutier-1@nasa.gov Steve Roy NASA Marshall Space Flight Center Huntsville, Ala. steven.e.roy@nasa.gov Ed Memi The Boeing Company Houston edmund.g.memi@boeing.com Adam K. Morgan The Boeing Company Houston adam.k.morgan@boeing.com
281-483-5111
Astronauts
281-483-5111
Science Operations
256-544-0034
281-226-4029
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PAO CONTACTS
OCTOBER 2009
OCTOBER 2009
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PAO CONTACTS
OCTOBER 2009