The SpaceX Falcon 9 rocket is seen as it launches from Vandenberg Air Force Base Space Launch Complex 4 East with the Jason-3 spacecraft onboard, , Sunday, Jan. 17, 2016, Vandenberg Air Force Base, California. Jason-3, an international mission led by the National Oceanic and Atmospheric Administration (NOAA), will help continue U.S.-European satellite measurements of global ocean height changes. Photo Credit: (NASA/Bill Ingalls)
The SpaceX Falcon 9 rocket is seen as it launches from Vandenberg Air Force Base Space Launch Complex 4 East with the Jason-3 spacecraft onboard, Sunday, Jan. 17, 2016, Vandenberg Air Force Base, California. Jason-3, an international mission led by the National Oceanic and Atmospheric Administration (NOAA), will help continue U.S.-European satellite measurements of global ocean height changes. Photo Credit: (NASA/Bill Ingalls)
The weather forecast is outstanding! And you can watch all the excitement live!
The primary goal is to deliver Jason-3 to low Earth orbit, where it will gather global measurements of ocean topography, or wave heights, using radar altimitry. These data provide scientists with essential information about global and regional changes in the Earth’s seas such as tracking sea level rise that threatens the resilience of coastal communities and the health of our environment. Continue reading “SpaceX Launching NASA Jason-3 Ocean Surveillance Satellite Jan. 17; with Barge Rocket Landing – Watch Live”
Special Guest: Dr. Steve B. Howell, Project Scientist on Kepler to discuss the great new results coming form the K2 mission – the repurposed Kepler mission.
Sierra Nevada Corporation's Dream Chaser spacecraft docks at the International Space Station.
Credits: Sierra Nevada Corporation
SNC’s Dream Chaser Spacecraft and Cargo Module attached to the ISS. Credit: SNC
A shuttle will soar again from American soil before this decade is out, following NASA’s announcement today (Jan 14) that an unmanned version of the Dream Chaser spaceplane was among the trio of US awardees winning commercial contracts to ship essential cargo to the International Space Station (ISS) starting in 2019.
Special Guest:Elizabeth S. Sexton-Kennedy, who works at FermiLab as Compact Muon Solenoid (CMS) Offline Coordinator. CMS (at CERN/LHC) is a particle detector that is designed to see a wide range of particles and phenomena produced in high-energy proton collisions in the LHC.
Falcon 9 first stage in pad 39A hangar at Kennedy Space Center following upright landing recovery from launch on Dec. 21, 2015. Credit: SpaceX
Now that SpaceX has successfully and safely demonstrated the upright recovery of their Falcon 9 booster that flew to the edge of space and back on Dec. 21 – in a historic first – the intertwined questions of how did it fare and what lies ahead for the intact first stage stands front and center.
Musk wants to see his "Red Dragon" on the surface of Mars within the next 20 years. Image Credit: SpaceX
There are several space stories we’re anticipating for 2016 but one story might appear — to some — to belong in the realm of science fiction: sometime in the coming year Elon Musk will likely reveal his plans for colonizing Mars.
Early in 2015, Musk hinted that he would be publicly disclosing his strategies for the Mars Colonial Transport system sometime in late 2015, but then later said the announcement would come in 2016.
“The Mars transport system will be a completely new architecture,” Musk said during a Reddit AMA in January 2015, replying to a question about the development of MCT. “[I] am hoping to present that towards the end of this year. Good thing we didn’t do it sooner, as we have learned a huge amount from Falcon and Dragon.”
Big Rockets
As far as any details, Musk only said that he wants to be able to send 100 colonists to Mars at a time, and the “goal is 100 metric tons of useful payload to the surface of Mars. This obviously requires a very big spaceship and booster system.”
He has supposedly dubbed the rocket the BFR (for Big F’n Rocket) and the spaceship similarly as BFS.
A sketch shows how the top section of the Mars Colonial Transporter might be configured. Credit: John Gardi.
Most online discussions describe the MCT as an interplanetary ferry, with the spaceship built on the ground and launched into orbit in one piece and perhaps refueled in low Earth orbit. The transporter could be powered by Raptor engines, which are cryogenic methane-fueled rocket engines rumored to be under development by SpaceX.
The future line-up of Falcon rockets is compared to the famous NASA Saturn V. The first Falcon Heavy launch is planned for 2015. Raptor engines may replace and upgrade Heavy then lead to Falcon X, Falcon X Heavy and Falcon XX. The Falcon X 1st stage would have half the thrust of a Saturn V, Falcon X Heavy and XX would exceed a Saturn V’s thrust by nearly 50%. (Illustration Credit: SpaceX, 2010)
The Challenge of Landing Large Payloads on Mars
While the big rocket and spaceship may seem to be a big hurdle, an even larger challenge is how to land a payload of 100 metric tons with 100 colonists, as Musk proposes, on Mars surface.
As we’ve discussed previously, there is a “Supersonic Transition Problem” at Mars. Mars’ thin atmosphere does not provide an enough aerodynamics to land a large vehicle like we can on Earth, but it is thick enough that thrusters such as what was used by the Apollo landers can’t be used without encountering aerodynamic problems such as sheering and incredible stress on the vehicle.
Another fan-based illustration of the modular sections of John Gardi’s MCT concept sitting on the surface of Mars. Credit: George Worthington. Used by permission.
With current landing technology, a large, heavy human-sized vehicle streaking through Mars’ thin, volatile atmosphere only has about 90 seconds to slow from Mach 5 to under Mach 1, change and re-orient itself from a being a spacecraft to a lander, deploy parachutes to slow down further, then use thrusters to translate to the landing site and gently touch down.
90 seconds is not enough time, and the airbags used for rovers like Spirit and Opportunity and even the Skycrane system used for the Curiosity rover can’t be scaled up enough to land the size of payloads needed for humans on Mars.
Artist’s rendering of a hypersonic inflatable aerodynamic decelerator technology concept. Credit: NASA.
NASA has been addressing this problem to a small degree, and has tested out inflatable aeroshells that can provide enough aerodynamic drag to decelerate and deliver larger payloads. Called Hypersonic Inflatable Aerodynamic Decelerator (HIAD), this is the best hope on the horizon for landing large payloads on Mars.
The Inflatable Reentry Vehicle Experiment (IRVE-3) was tested successfully in 2012. It was made of high tech fabric and inflated to create the shape and structure similar to a mushroom. When inflated, the IRVE-3 is about 10-ft (3 meter) in diameter, and is composed of a seven giant braided Kevlar rings stacked and lashed together – then covered by a thermal blanket made up of layers of heat resistant materials. These kinds of aeroshells can also generate lift, which would allow for additional slowing of the vehicle.
“NASA is currently developing and flight testing HIADs — a new class of relatively lightweight deployable aeroshells that could safely deliver more than 22 tons to the surface of Mars,” said Steve Gaddis, GCD manager at NASA’s Langley Research Center in a press release from NASA in September 2015.
NASA is expecting that a crewed spacecraft landing on Mars would weigh between 15 and 30 tons, and the space agency is looking for ideas through its Big Idea Challenge for how to create aeroshells big enough to do the job.
With current technology, landing the 100 metric tons that Musk envisions might be out of reach. But if there’s someone who could figure it out and get it done, Elon Musk just might be that person.
View of upper dome and newly attached crew access tunnel of the first Boeing CST-100 ‘Starliner’ crew spaceship under assembly at NASA’s Kennedy Space Center. This is part of the maiden Starliner crew module known as the Structural Test Article (STA) being built at Boeing’s refurbished Commercial Crew and Cargo Processing Facility (C3PF) manufacturing facility at KSC. Numerous strain gauges have been installed for loads testing. Credit: Ken Kremer /kenkremer.com
KENNEDY SPACE CENTER, FL – Buildup of the first of Boeing’s CST-100 Starliner crew spaceships is ramping up at the company’s Commercial Crew and Cargo Processing Facility (C3PF) – the new spacecraft manufacturing facility at NASA’s Kennedy Space Center.
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