TAU-SAT1, Tel Aviv University's first nanosatellite, was launched into orbit on Saturday Feb. 20 at 07:36 p.m. (Israel time), from the NASA launch facility in Virginia, USA. TAU-SAT1 will conduct several experiments while in orbit, including the measurement of cosmic radiation around earth.
TAU scientists are excited with the remarkable scientific and technological achievement, noting that the nanosatellite is the first to be wholly designed, developed, assembled and tested at an Israeli university. The work was done at the Center for Nanosatellites, an interdisciplinary endeavor between the Iby and Aladar Fleischman Faculty of Engineeringand the Porter School of the Environment and Earth Sciences at the Raymond and Beverly Sackler Faculty of Exact Sciences and the Soreq Nuclear Research Center.
TAU completed the construction of TAU-SAT1 about four months ago, sending it for pre-flight testing at the Japanese space agency JAXA. About two weeks ago the nanosatellite arrived at its final stop prior to liftoff, Wallops Island in Virginia, USA - where it 'cached a ride' on a NASA resupply spacecraft destined for the International Space Station (ISS).
"It's a big day for TAU," says Prof. Colin Price, Head of the Porter Department of Environmental Studies. "We have now joined the 'Civil Space Revolution,' called New Space, in which, unlike the Old Space, not only giant companies with huge budgets and large teams of engineers can build and launch satellites.
A few years ago we established the Center for Nanosatellites, with the goal to build small 'CubeSat' for research purposes. Since then we were able to prove that with the right planning, miniaturization and modulation of many technologies, small satellites can be built and launched into space within two years by students, at a fraction of the budget needed in the Old Space."
"This is a nanosatellite, or miniature satellite, of the CubeSat variety," explains Dr. Ofer Amrani, Head of Tel Aviv University's Miniature Satellite Lab. "The satellite's dimensions are 10 by 10 by 30 cm, and it weighs less than 2.5 kg. TAU-SAT1 is the first nanosatellite designed, built and tested independently in an Israeli university by researchers and students."
Dr. Meir Ariel, Director of TAU's Center for Nanosatellites, says: "We know that that there are high-energy particles moving through space that originate from the sun's cosmic radiation. Our scientific task is to monitor this radiation, and to measure the flux of these particles and their products.
It should be understood that space is a hostile environment, not only for humans but also for electronic systems. When these particles hit astronauts or electronic equipment in space, they can cause significant damage. The scientific information collected by our satellite will enable the design of protective means for astronauts and space systems. To this end, we incorporated into the satellite a number of experiments, developed by our partners at SNRC's Space Environment Department, who will also conduct the relevant scientific research."
Another challenge that presented itself was how to extract the data collected by the TAU-SAT1 satellite. At an altitude of 400 km above sea level, the nanosatellite will orbit the earth at a dizzying speed of 27,600 km per hour, or 7.6 km per second, completing a circuit around Earth every 90 minutes.
"In order to collect data, we built a satellite station on the roof of the Engineering building," says Dr. Amrani. "Our station, which also serves as an amateur radio station, includes a number of antennas and an automated control system. When TAU-SAT1 passes 'over' Israel, that is, within a radius of a few thousand kilometers from the ground station's receiving range, the antennas will track the satellite's orbit and a process of data transmission will occur between the satellite and the station.
Such transmissions will take place about four times a day, with each one lasting less than 10 minutes. In addition to its scientific mission, the satellite will also serve as a space relay station for amateur radio communities around the world. In total, the satellite is expected to be active for several months. Because it has no engine, its trajectory will fade over time as a result of atmospheric drag - and eventually it will burn up in the atmosphere and come back to us as stardust."
TAU researchers are already aiming for their next target - TAU-SAT2: "We built the infrastructure for developing TAU-SAT1 on our own - from the cleanrooms, through the various testing facilities such as the thermal vacuum chamber, to the receiving and transmission station we placed on the roof.
Now that the infrastructure is ready, we can begin to develop TAU-SAT2. The idea is that any researcher and any student, from any school at Tel Aviv University, or outside of it, will be able to plan and launch experiments into space in the future - even without being an expert on space."
+ See related video here
|Thanks for being there;
We need your help. The SpaceDaily news network continues to grow but revenues have never been harder to maintain.
With the rise of Ad Blockers, and Facebook - our traditional revenue sources via quality network advertising continues to decline. And unlike so many other news sites, we don't have a paywall - with those annoying usernames and passwords.
Our news coverage takes time and effort to publish 365 days a year.
If you find our news sites informative and useful then please consider becoming a regular supporter or for now make a one off contribution.
|SpaceDaily Monthly Supporter
$5+ Billed Monthly
$5 Billed Once credit card or paypal
Research highlights ways to protect astronaut cardiovascular health from space radiation
Washington DC (SPX) Feb 15, 2021
Space: the final frontier. What's stopping us from exploring it? Well, lots of things, but one of the major issues is space radiation, and the effects it can have on astronaut health during long voyages. A new review in the open-access journal Frontiers in Cardiovascular Medicine explores what we know about the ways that space radiation can negatively affect cardiovascular health, and discusses methods to protect astronauts. These include radioprotective drugs, and antioxidant treatments, some of which ... read more