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  • For the third time, SpaceX is launching the most powerful operational rocket in the world.

  • The Falcon Heavy stands at 70 meters tall, packs-in 5 million pounds of thrust at liftoff,

  • AND can carry nearly 64 metric tons in payload into low earth orbit; more than twice its

  • closest competitor.

  • The mission is already checking off a lot offirsts”, not only for the groundbreaking

  • experiments onboard that we'll definitely get to later, but also for SpaceX.

  • The Falcon Heavy made some astounding accomplishments in the last year, starting with its debut

  • launch in February of 2018.

  • And just recently in April 2019, the Falcon Heavy had its first commercial launch and

  • the mission successfully landed all three of its boosters, including the difficult landing

  • of its center core on the off-coast drone ship, Of Course, I Still Love You, a first

  • for SpaceX.

  • Now those same rockets are going to be reused as the side boosters for the next Falcon Heavy

  • mission for the very first time.

  • If SpaceX pulls off the Department of Defense's Space Test Program 2 mission, the rocket will

  • blaze the trail for SpaceX to fly humans to the moon, and one day, even Mars.

  • This STP-2 launch is a first with the DoD and U.S. Air Force Space and Missile Systems

  • Center, and the experiments within the payload range from those put forth by government facilities

  • like NASA and NOAA, to the U.S. military and even research projects from universities.

  • In total, the payload is filled with 24 different sized satellites, making this deployment one

  • of the most diverse ever. And deploying all of these satellites will be among the most

  • complex tasks in SpaceX's history and everyone is watching for their success.

  • No pressure Elon.

  • But what makes this launch even more special isn't just that it's such a huge defining

  • moment for SpaceX, it's also because of what the Falcon Heavy is carrying.

  • On board, this hefty vehicle are three experiments that if successful, could alter how we explore

  • the solar system in the future.

  • Firstly, LightSail 2 will be the first solar sail spacecraft to orbit the earth, next up is the Green Propellant

  • Infusion Mission testing their alternative rocket fuel, and lastly the Deep Space Atomic

  • Clock which will help spacecraft with more precise and autonomous radio navigation. But

  • let's start with the one that sounds the most science-fictiony, but is definitely reality.

  • Solar sailing is technology using the sun's light to propel spacecraft; no fuel, no expelling

  • of energy, no toxic by-products.

  • So solar sailing uses the push of light.

  • It's actually photons which have no risk mass, but in relativistic land, they actually carry

  • momentum.

  • So as the photons hit something, in, particularly if they hit and bounce off, then you end up

  • getting a momentum transfer that pushes your spacecraft.

  • When you get into the vacuum of space, that push actually becomes significant.

  • For this mission, LightSail 2 is encapsulated within a spacecraft built at Georgia Tech,

  • inside Prox-1, and will deploy at a height of seven hundred and twenty kilometers above

  • the earththe optimal range for solar sailing.

  • But how will we know if it's successful?

  • So we're trying to demonstrate that we actually are doing controlled solar sailing by raising

  • the orbit, or more formally, increasing the orbital energy.

  • And what we're looking for is anything measurable.

  • We have all retroreflectors on there, and the International Laser Ranging service will

  • be shooting lasers at it and then measuring the time to come back.

  • That may give us an indication very quickly within a couple of days if it works.

  • If successful, LightSail 2 will become the first spacecraft in Earth's orbit to fly

  • on sunlight alone, and this would be a gamechanger for nanosatellites like CubeSats.

  • These already cost-effective satellites won't have to carry fuel.

  • And this will enable them to live longer lifetimes, or tackle more challenging orbits, which will

  • then change the way we explore space entirely.

  • This tantalizing future of space travel is probably why the project has gotten so much

  • support over the years and means so much to the LightSail team.

  • LightSail 2 is also different because it is completely funded by individuals, more than

  • 40,000 people have contributed money to the LightSail project.

  • So it really is the project that represents a huge interest in space exploration.

  • If you're lucky you might just be able to see this historic mission in orbit while it

  • runs its course.

  • But LightSail 2 isn't the only experiment onboard with the goal of more sustainable

  • space missions in the future.

  • NASA is collaborating with Ball Aerospace & Technologies Corporation and Aerojet Rocketdyne

  • to create the Green Propellant Infusion Mission or GPIM.

  • For over ten years, researchers have been developing a new low-toxicity, propellant

  • blend called hydroxyl ammonium nitrate,

  • also known as AF-M315E.

  • Essentially, what makes this fuel better than hydrazine is that it's over 40% denser,

  • which means we can store more of it in the same size containers, and whereas hydrazine

  • needed the lining of its containers to be constantly warmed, AF-M315E can't freeze.

  • Which requires less power from the spacecraft to maintain the fuel's temperatures.

  • Basically, it yields higher performance, it's cheaper, it's less toxic, and researchers just

  • need to prove that it works in space.

  • And if it does, we'll be able to travel further into deep space than ever before.

  • But, as with any spacecraft, we also need to be able to control and navigate where it's

  • going, and that's the goal of the Deep Space Atomic Clock.

  • This mission aims to give spacecraft the autonomous ability to calculate its own trajectory with

  • the use of an atomic clock in conjunction with an onboard Artificial Intelligence system.

  • The Deep Space Atomic Clock is the very first ion-based space clock, the first that can

  • keep time very stably that's small enough that we can send it in a space, it's about

  • 50 times more stable than the GPS clocks, the cesium rubidium clocks.

  • Stability for this atomic clock means that it should only lose a second in 10 million

  • years.

  • And that's important because a second can mean landing on Mars or missing your target

  • by miles.

  • The success of its timekeeping is due to the mercury ions involved in the technology, which

  • the clock is the first to use.

  • What's really cool about using ions is that we can trap them electromagnetically to confine

  • them in a vacuum tube and confined them by EM fields.

  • So they're not actually hitting the walls of their containment trap, which essentially

  • means that the clock is much more stable over long periods of time.

  • And its performance is on par with the atomic clocks that we use on the ground in the Deep

  • Space Network.

  • But they're the size of a refrigerator, so not really something that we can send on a spacecraft.

  • The Deep Space Network is the world's largest and most sensitive scientific telecommunications

  • system.

  • It's made up of 3 facilities placed very strategically around the world so we

  • never lose a connection with a spacecraft.

  • But right now, it's a two-way relay system to give spacecraft directions, which can take

  • anywhere from minutes to hours, and the Deep Space Atomic Clock could help manage that.

  • If you can keep track of that signal, then we can just blast radio signals from the Deep

  • Space Network to our spacecraft, wherever they're traveling in the solar system.

  • And they can collect that signal on board, and then time tag it.

  • And then your computer needs to be programmed as such that it can actually perform the navigation

  • algorithms that people like me would do here on the earth.

  • We haven't flown this clock technology before.

  • So being able to fly this and demonstrate it in space is an absolutely huge milestone

  • for us.

  • And there's more than just making sure that spacecraft know where they're going.

  • If tests and demonstrations go well, the Deep Space Atomic Clock could one day help maintain

  • daily life on other planets.

  • We use GPS every single day here on Earth, and when we think about sending astronauts

  • to places like the moon or Mars or even beyond that, they're going to need a way to find

  • their way around the surface of that planet or moon, right?

  • They're going to need a way to navigate from, say, I don't know, whatever their field experiment

  • location is back to home base.

  • And by having a GPS like navigation system there, we can support that human presence

  • and the human ability to navigate on those foreign places.

  • After deployment via the Falcon Heavy, the Deep Space Atomic Clock won't turn on until

  • 4-7 weeks after lift-off that point, the real excitement starts for the deep space team.

  • The Falcon Heavy STP-2 mission has enormous future applications ahead, the kind that can

  • get us off the ground, into space, and beyond.

  • There are so many upcoming missions for this year, if you want to keep up with them subscribe!

  • And check out this Countdown to Launch here, where we talk about SpaceX-CRS17 mission from

  • just a couple months ago.

  • Thanks for watching and we'll see you next time on Seeker.

For the third time, SpaceX is launching the most powerful operational rocket in the world.

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SpaceX的 "獵鷹重型 "正在發射迄今為止最複雜的任務之一。 (SpaceX’s Falcon Heavy Is Launching One of its Most Complex Missions Yet)

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    林宜悉 發佈於 2021 年 01 月 14 日
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