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Space NASA

NASA Selects Bold Proposal To 'Swarm' Proxima Centauri With Tiny Probes (universetoday.com) 113

In order to reach places like Alpha Centauri this century, we'll need to utilize gram-scale spacecraft that rely on directed-energy propulsion. To that end, NASA has selected the Swarming Proxima Centauri project for Phase I development as part of this year's NASA Innovative Advanced Concepts (NIAC) program. According to Universe Today, Swarming Proxima Centauri is "a collaborative effort between Space Initiatives Inc. and the Initiative for Interstellar Studies (i4is) led by Space Initiative's chief scientist Marshall Eubanks." From the report: According to Eubanks, traveling through interstellar space is a question of distance, energy, and speed. At a distance of 4.25 light-years (40 trillion km; 25 trillion mi) from the Solar System, even Proxima Centauri is unfathomably far away. To put it in perspective, the record for the farthest distance ever traveled by a spacecraft goes to the Voyager 1 space probe, which is currently more than 24 billion km (15 billion mi) from Earth. Using conventional methods, the probe accomplished a maximum speed of 61,500 km/h (38,215 mph) and has been traveling for more than 46 years straight.

In short, traveling at anything less than relativistic speed (a fraction of the speed of light) will make interstellar transits incredibly long and entirely impractical. Given the energy requirements this calls for, anything other than small spacecraft with a maximum mass of a few grams is feasible. [...] In contrast, concepts like Breakthrough Starshot and the Proxima Swarm consist of "inverting the rocket" -- i.e., instead of throwing stuff out, stuff is thrown at the spacecraft. Instead of heavy propellant, which constitutes the majority of conventional rockets, the energy source for a lightsail is photons (which have no mass and move at the speed of light). But as Eubanks indicated, this does not overcome the issue of energy, making it even more important that the spacecraft be as small as possible. "Bouncing photons off of a laser sail thus solves the speed-of-stuff problem," he said. "But the trouble is, there is not much momentum in a photon, so we need a lot of them. And given the power we are likely to have available, even a couple of decades from now, the thrust will be weak, so the mass of the probes needs to be very small -- grams, not tons."

Their proposal calls for a 100-gigawatt (GW) laser beamer boosting thousands of gram-scale space probes with laser sails to relativistic speed (~10-20% of light). They also proposed a series of terrestrial light buckets measuring a square kilometer (0.386 mi2) in diameter to catch the light signals from the probes once they are well on their way to reaching Proxima Centauri (and communications become more difficult). By their estimates, this mission concept could be ready for development around midcentury and could reach Proxima Centauri and its Earth-like exoplanet (Proxima b) by the third quarter of this century (2075 or after). [...] Eubanks and his colleagues hope that the development of a coherent swarm of robotic probes will have applications closer to home. Swarm robotics is a hot field of research today and is being investigated as a possible means of exploring Europa's interior ocean, digging underground cities on Mars, assembling large structures in space, and providing extreme weather tracking from Earth's orbit. Beyond space exploration and Earth observation, swarm robotics also has applications in medicine, additive manufacturing, environmental studies, global positioning and navigation, search and rescue, and more.

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NASA Selects Bold Proposal To 'Swarm' Proxima Centauri With Tiny Probes

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  • by Anonymous Coward
    ... how are they imparting inertia?
  • No (Score:5, Interesting)

    by Arnonyrnous Covvard ( 7286638 ) on Thursday January 11, 2024 @02:28AM (#64148853)

    Don't present science fiction this way. You cannot aim sufficient energy over distances like that and you can't slow these gram-weight "robots" down with this propulsion system. They're either going to go too slow or just become tiny meteorites once they get there. It won't matter though because communication from a tiny probe that far away right next to a star is going to be impossible. It's a slush fund project.

    • So you're saying Phase I contracts for a program aimed at radically advanced concepts at NASA should avoid "science fiction," huh? Or are you suggesting you have a firmer grip on the laws of physics than professional scientists and engineers?
      • Re:No (Score:5, Funny)

        by Arnonyrnous Covvard ( 7286638 ) on Thursday January 11, 2024 @02:58AM (#64148931)

        I have a firmer grip on funding shenanigans than you, apparently.

        • The ten different projects are sharing $175k. So unless you imagine the people on both sides of the selection process went through all of this to finance a weekend in Vegas, you're talking out of your ass.
          • So if the bridge that I have to sell to you is cheap enough upfront, you'll buy?

            • What kind of misanthropic POS believes people pursue careers in science just to con institutions out of pocket change?

              People actually familiar with NASA know the gaming is overwhelmingly at the high-funding end of the scale. NIAC is extremely valuable.
              • What kind of misanthropic POS believes people pursue careers in science just to con institutions out of pocket change?

                People who don't like the results science produces.

                • People who don't like the results science produces.

                  Indeed. And perhaps moral revenge for feeling inferior to those who do important work.

            • If I can charge tolls from the travelers over the bridge: certainly.

              • And if I tell you my bridge design is made out of forcefields and holograms, which might exist by 2075, will you still give me a $100k today to get to work on it? $10k? A dollar? The time of day?

                • Well, I said: if I can collect road tolls.
                  I doubt that is possible on a hologram.

                  But we could try. With you as business partner: what could go wrong?

                  • Some people apparently don't know what "I have a bridge to sell you" means. Hint: It's a reference to a conman. [wikipedia.org] You do not get the bridge. It means I think you're gullible, because you are willing to spend money on empty promises. The price doesn't matter.

                    • No, actually what it means is that people recognise the parallel you're trying to make, and do not think it is an appropriate parallel.

                      Do you understand what the word "research" means? It means "we don't know what we're doing, or if it'll work". And the point of "Phase 1" studies is to work out what would be required, and if those technologies could be made to work (or if the idea would need redesign to be more achievable).

                      If you don't like it, feel free to spend the rest of your life working up the greas

                    • As a human and a tax payer, I prefer "my money" to be spent on space research, instead on a cheaper bomb to kill the kids on a wedding in a desert.

                      Regarding research: there are different phases, inception, conception, can it be done etc.

                      If you do not want to put your money into research up to you.

                • by catprog ( 849688 )

                  So in return for $100k I get progress on forcefields and holograms?

                  Assuming the proposal for the hologram and force field progress is possible and I had the science funding it would go into the pile of things to look into further.

              • The tolls over the bridge are better than the trolls under it.
            • Re: (Score:3, Informative)

              by Opportunist ( 166417 )

              If the price is low enough, the scrap value of the bridge and the real estate it's one may well be worth it.

              This project sounds like it's some basic research for a future "real" project that needs some spiffy, publicity-garnering tackle. If those 175k lead to us being able to do some real interstellar research somewhere in the next half century, that's money well spent, but if you try to just tell the people "We're gonna spend 175k on researching something you'll never get to see anything of", it's a pretty

      • Amplifying on this, it's not until after Phase III that projects might graduate to become government or industry R&D projects: NIAC phases. [nasa.gov] Not all years [nasa.gov] even have Phase III grants.
        • Yes, exactly. Phase I is literally a concept study, which one could consider (at the limit) a scientific investigation of science-fiction ideas. The earlier commenter was smugly accusing NIAC of doing exactly what Phase I says it does, like he had uncovered a conspiracy.
    • Re:No (Score:5, Funny)

      by fahrbot-bot ( 874524 ) on Thursday January 11, 2024 @03:04AM (#64148943)

      They're either going to go too slow or just become tiny meteorites once they get there.

      But what could be friendlier than (basically) firing bird-shot using a giant death-ray at an alien system. There's no way any inhabitants could possibly mistake that as anything bad ... :-)

      [*cough* Klendathu *cough*]

      • A 10GW laser is only a death ray when you look straight into it from a few giga meters distance with your remaining eye.

        • A 10GW laser is only a death ray when you look straight into it from a few giga meters distance with your remaining eye.

          TFS notes it's a 100 GW laser, not 10 (in case your's isn't a typo) ...

          • The tyop was in using Gm instead of Tm.
          • Oh, I indeed saw 10 and not 100, thanx.
            Regarding the deathray point. I guess such a thing needs to be in orbit, to be able to be pointed the same way for weeks.
            Depending on wavelength such a laser would indeed be WMD, if the laser can penetrate the atmosphere.

    • you can't slow these gram-weight "robots" down with this propulsion system.

      A fly-by mission can collect a lot of data.

      The Pluto mission was a fly-by. So was Voyager.

      • A fly-by mission can collect a lot of data.

        No argument there, but if the probe can't send that data back to Earth what's the point in the mission?

        • The probes will sent data back.
          Probes will drop out of the stream every few light seconds and form a relay for data transmissions home.

          • You never took a telecom class in college, did you?

            • I never was on a college.
              I jumped from High School to University.

              Well, actually I'm on a college right now. But that is English Teacher TESOL program and has nothing to do with CS. I try to switch to an Solar Energy/CS PhD program, but my native language skills are a problem ATM.

              I doubt the probe swarm has any contract/SIM card with any majour telecom providers, though.

          • Probes will drop out of the stream every few light seconds .

            Ah yes, these gram sized probes with their motors of some kind, and their science collection instruments, and their insterstellar class transmitters and their power sources to run all that shit. I'm sure that's exactly what they will do.

            • Ah yes, these gram sized probes with their motors of some kind,

              No, the ones that drop out "feather" (sailing term) their beam-collecting device to reduce the propulsion they receive, so that they drop back with respect to the bulk of the swarm. Since the mission construction is intended for a single flyby phase (with an extended playback phase - see the several years it took to get New Horizons data from spacecraft to Earth, both times), you can also launch the main swarm (phased in velocity to arrive en ma

            • by catprog ( 849688 )

              4.2 lightyear / 5.3712 billion km (pluto distance) = 7 397.64285

              Their is a power source from the beamed light.

              If we can get the probe to transmit from Pluto to Earth then it can transmit to the next probe that is further back in distance.

              -

              Yes their is going to be a lot of research needed to get this to happen but this is what the funding is for.

      • In addition to the problem of sending back data, at 10% lightspeed it's more a shot-by than a fly-by.
        Well, on the other hand that would mean very few data to send back, which may help...

        • by AmiMoJo ( 196126 )

          Reading the proposal, that's why they are sending a swarm. The idea is that they all sync clocks using laser pulses from Earth, and then all flash back simultaneously. With enough of them it's hoped that the signal can be received, but you still need massive reflectors on Earth to capture the light.

    • (I happen to know one of the people involved.)

      You cannot aim sufficient energy over distances like that

      They were originally intended to be powered by betavoltaic batteries (solar cell sandwich with a charged particle emitter for the peanut butter - like the "radioactive diamond" batteries but with Strontium 90 for the radiation source). But another dude computed what local interstellar hydrogen looked like when treated as a proton/electron beam at 20% of light speed and concluded no other radiation source

      • You cannot aim sufficient energy over distances like that
        [description of betavoltaic battery run off "interstellar wind" of high-speed travel]

        Oh, yes...

        You CAN aim the propulsion energy well enough for long enough to get them up to 20%ish of lightspeed. After that the energy is stored in their momentum relative to that of the interstellar gas. You don't have to keep powering them from home and there's far more than you need to power them for the rest of the mission.

        • But you can't build a 100GW laser. Even if the Russian oligarchs who funded an earlier iteration of this study at UCSB really really want a 100GW laser.

          • That's enough power to send 80+ DeLoreans into the past.
          • But you can't build a 100GW laser. Even if the Russian oligarchs who funded an earlier iteration of this study at UCSB really really want a 100GW laser.

            It'll probably be a space laser, so guessing it will be built by not Russians [nymag.com] ... :-)

    • AXIS would disagree.

    • 'you can't slow these gram-weight "robots" down with this propulsion system'

      If you're going to cry "science fiction" then you should include that there is already at least one solution in the literature. Robert L. Forward included a solar sail that could decelerate in _Rocheworld_ forty years ago.

    • Re:No (Score:4, Informative)

      by John Cavendish ( 6659408 ) on Thursday January 11, 2024 @10:39AM (#64149667)

      Well maybe you are the biggest fish in financing, however this is a well known and discussed for some time concept of sending micro space-probes called Breakthrough Starshot [wikipedia.org] - supported by e.g. Seven Hawking, but who is he to compare with your vast scientific expertise.

      Yes, the communication is a problem - one of many challenges, which this project is facing, and which is being worked out.

      Despite vast financing from Yuri Milner every once a while NASA add some funding to one of the components of this project via NIAC mostly. If you followed NIAC (I am sorry, for sure you must followed, so just to remind), it is a program to support innovative concepts and some of them a pretty wild, yet always very interesting.

    • The idea, I think, is to use 'spare change' to fund some crazy shit on the off chance it'll work out somehow. The problem is that this proposal is obviously crap. No, a 1g probe cannot carry a useful sensor package, cannot carry a useful processor, and cannot carry a useful signal generator. Even if you ignore the signal issue, there's still nothing a 1g hardware package could do that we couldn't do - and do better - with a space-based telescope much, much closer to Earth.

      At least with the reactionless

    • cogent arguments. If there is no proposal for deceleration, then how would the beasties slow down? If they are so far from earth, then how will they communicate? I mean, a measly 60 watt signal aimed via a... oh, yeah, gram-weight satellite, so no reasonable antenna or aiming system. I am all for exploring Proxima Centauri, but.... this sounds more like sending some very tiny missiles through that star system.
      • by catprog ( 849688 )

        How did the voyagers and new horizons slow down after visting the planets?

        As for communicating you send a relay of probes to pick up the signal and pass it on.

        -

        This is why it is such a small amount. It is a maybee this will work so lets have a look at it.

    • and you can't slow these gram-weight "robots" down with this propulsion system

      Actually, for a different iteration of this mission design, that's not so much of a problem. With "sails" designed for initial acceleration by maser radiation, but also capable of reflecting sunlight, to get to Proxima Centauri, you aim the spacecraft at Alpha (or Beta, same difference) Centauri, decelerating from the initial maser boost for a lot of the route, then do a "sundive + slingshot" around Alpha (or Beta) to come out wit

  • by backslashdot ( 95548 ) on Thursday January 11, 2024 @02:43AM (#64148901)

    How about something more practical today like a flotilla of probes to orbit and land on Halley's Comet before the ice starts evaporating?

  • Physics (Score:5, Insightful)

    by Roger W Moore ( 538166 ) on Thursday January 11, 2024 @03:00AM (#64148933) Journal

    They also proposed a series of terrestrial light buckets measuring a square kilometer (0.386 mi2) in diameter

    Diameters are not measured in square kilometres.

    "Bouncing photons off of a laser sail thus solves the speed-of-stuff problem,"

    Stuff doesn't have a problem with speed. This is not a recognized problem.

    "But the trouble is, there is not much momentum in a photon, so we need a lot of them.

    There is as much momentum in a photon as you want to give it. The photons you plan to use may not have much momentum but that's not a general property of all photons and there is no upper limit to a photon's momentum.

    The claim that it is more energy efficient to send a swarm of gram-sized probes instead of fewer, larger probes also makes no sense: the total mass determines the energy requirements not how it is shared between the probes. There is also zero discussion of the aims of doing this. Are we really going to learn much at all from what will probably be little more than a swarm of randomly oriented webcams passing through a solar system at 20% of the speed of light? There will be zero chance to tell them to point at any planets given the signal delay.

    • Re:Physics (Score:4, Funny)

      by 93 Escort Wagon ( 326346 ) on Thursday January 11, 2024 @03:50AM (#64148995)

      Picky picky picky. Next I suppose you're gonna pick apart the Millennium Falcon's 12-parsec Kessel Run record...

    • Also how would a gram probe beam back any information back to earth, because of the total power available to these things, and because they would be right between us and the blinding light from the star.

      • The probes will collect energy from the star.

        They will use a directional RF beam in a frequency not generated by stars.

        Stars emit synchrotron radiation [wikipedia.org] in a wide RF spectrum. The probes will emit in a very narrow spectrum.

    • there is no upper limit to a photon's momentum.

      Maybe. Some physicists believe there is an upper limit when the wavelength reaches a Planck length.

      L = 1.6e-35 meter.

      F = 3e8 / 1.6e-35 = 1.8e43 Hz.

      E = hF = (6.6e-34) * (1.8e43) = 12 billion joules

      • True, I should have said that there is no known upper limit to a photon's momentum since it is not at all clear what happens at the Planck scale.
    • If you're gonna be pedantic, do it right.

      There is as much momentum in a photon as you want to give it.

      There's as much momentum in a [specifically photons aimed at this device] as you can give it, not as much as you want to give it.

      And guess what? We can't actually give them very much.

      Are we really going to learn much at all from what will probably be little more than a swarm of randomly oriented webcams passing through a solar system at 20% of the speed of light?There will be zero chance to tell them to po

      • by AmiMoJo ( 196126 )

        TFA doesn't say, but maybe they intend to brake by turning their sails to face the target star. It will lengthen the journey, but might allow them more time to capture data.

        I just hope there is nobody living there, or they might be alarmed by high speed artificial objects aimed at them.

        • Nothing like blasting away with a relativistic shotgun to show you mean business.

          Plugging the numbers, 10g at 0.3c has the energy of about 10kT of TNT. It wouldn't be like a nuclear bomb going off if it hit something, it would be a nuclear bomb going off, since IIUC, 0.3c is fast enough that it's going to cause fusion with whatever it smacks into.

          On the other hand, I guess it's very very very unlikely to hit

      • Surprisingly: Beta Centaury has an Earth like planet.
        Could one make to believe on gods, but probably just a stupid incredible unlikely coincident.
        But it is as it is: the closest star system to Earth, has an Earth like planet. Believe it or not.

        • by dryeo ( 100693 )

          Beta Centauri is only related to Alpha Centauri by being in the same constellation and part of the southern cross, from our view point and is an order of magnitude (390 LY) further away. Can't find anything about a planet and considering the type of star the main one is, life is unlikely.
          Perhaps you meant Proxima Centauri, the closest star currently which does have an Earth sized planet at the right distance to possibly have liquid water. Problem is the planet is tidally locked orbiting a flare star, which

      • There's as much momentum in a [specifically photons aimed at this device]

        That's not what they wrote though they said that there is not much momentum in _a_ photon making it sound as if they were talking about all photons. Were they referring to just their photons then "the photons" would have been the correct term. Use of the indefinite article changes the meaning to include any photon in general. Perhaps I was being too pedantic but I was definitely doing pedantic right! ;-)

    • In nitpicking mode today?
      Asking for a friend.

    • My god the quality of tech reporting has truly reached Gen Z levels.

    • I totally agree with all of your criticisms. To me the greatest benefit of this idea (if it works) is that there is huge redundancy. Flying interstellar objects can take out some of the units and others might still make it.
      One complex system is more vulnerable to failure than a bunch of spatially distributed/redundant systems.
  • by Anonymous Coward

    In the unlikely event that there's any intelligent life nearby, we should err on the side of caution and not go firing relativistic anything until we have some ability to divert it, should it turn out that the swarm is approaching something we didn't intend to destroy.

    • by dargaud ( 518470 )
      They'd probably see the laser light use to push the probe a decade in advance...
    • Klaatu barada nikto indeed.
    • It’s the total energy, not the speed. Cosmic rays travel at only a very tiny sliver under light speed. A 4.5 gram mass traveling at about .1C is around 2 million mega joules, about the same energy as a 10k lb mass moving at 67k mph. So substantial, but very unlikely to hit any planet and if there was an atmosphere it probably wouldn’t make it to the surface with such little mass.
      • by dryeo ( 100693 )

        It would be going fast enough that it probably wouldn't have time to burn up and may hit the atmosphere hard enough that the atoms in its way would under go fusion

        • The same could be said of cosmic rays though, and they do not. Only byproducts of them make it to the surface to do things like flip bits. A mass that small would immediately turn into a sphere like shape and spread out, with such little mass it certainly wouldn’t make it through intact. However a large mass with far less velocity would, the more mass and less speed the more intact. If the planet had a thin atmosphere like mars it’s more likely to reach further down, with something as thin a
          • by dryeo ( 100693 )

            An object with a mass of a gram, perhaps half a cubic centimeter in volume, is much different then a cosmic ray which usually consist of a few protons/neutrons enlarged by relativistic speeds.
            I don't know enough to say what would happen, so perhaps you're right and it would burn up in the 0.003 seconds it takes to traverse the lower 100 miles of atmosphere. We're talking about an object going perhaps 37,000 mile per second, depending if it slowed down much on the trip.

            • Given a drag coefficient of .8 and a speed of .1C a rough napkin calculation yields 20 quadrillion watt seconds of power, so much that it’s 2000 times the power of the Hiroshima bomb. Granted, I did not use the relativistic calculation for drag which makes this an under estimate. I guarantee 3ms is enough time for that much power to evaporate a few grams and turn it into a large sphere which won’t make it to the ground.

              Its so much energy it couldn’t possibly survive the journey to the
              • by dryeo ( 100693 )

                Wouldn't it just turn into a ball of plasma still moving at the same speed? Seems to me that the atoms in front of it would also get severely compressed as no time to get forced to the side, and would heat up or even start fusing.
                You may have a point about the trip, a one gram object could easily have its trajectory changed, Voyageurs trajectory was changed just by heat.
                Personally, I have a hard time with a one gram object having a good enough power supply, computer, means of changing its trajectory, useful

                • It would instantly turn into a very large insanely expanding ball of plasma which would exponentially increase the drag force so it wouldn’t impact.

                  I have a hard time with a one gram object having a good enough power supply, computer, means of changing its trajectory, useful sensors and the means to communicate across light years.

                  Yea, it’s a bit beyond what we can do. I’m assuming it would have some kind of ultra light solar sail to somehow do in flight corrections but that only adds to the cross sectional area. I’m guessing anything going at .1C needs shields in the form of an insanely narrow cross section design and the first 20% something insanely dense and t

  • by Anonymous Coward

    "Given the energy requirements this calls for, anything other than small spacecraft with a maximum mass of a few grams is feasible"

    What exactl does this doodle mean? It's not a sentence. It suggess only large spacecraft [are] feasible. The rest of the article implies the opposite.

    Can anyone who understands this please translate?

  • We are Bob...
  • Sending the probes with a laser is the easy part, you would need to string a hundred thousand as repeaters to get any signals back. This requires enormous resources and ground based propulsion and is the hard way to get close up views of exoplanets. Instead, use the sun as a gravitational lens [universetoday.com] to get a 50 billion times resolution boost and put a modest telescope at the focal point. We can unwrap the image with extreme precision because we know the mass distribution of our solar system so well. We would
  • Electrons travel at ~ .1c
    I'm highly doubtful that we can accelerate whole molecules faster than that.

    • Electrons travel at ~ .1c I'm highly doubtful that we can accelerate whole molecules faster than that.

      Electrons can go a lot faster than that. If you plug 100GeV from the Large Electron-Positron Collider into this calculator [omnicalculator.com] you get more than 99.9% of the speed of light. Likewise for lead ions at >500TeV [stackexchange.com] in the Large Hadron Collider.

      • You totally missed the point!

        How fast can a *MOLECULE* be accelerated?
        Try water, for instance.

        • Yes, I did miss the point you were making. From this article [i4is.org] it looks like 10 minutes of acceleration to get to 0.2c, which I think is an acceleration of 17000g. I have no idea if this is feasible. It should be possible to reach high speeds with gentler acceleration, though. For example, 120 days at 1g should achieve the same speed as 10min at 17000g.

  • Maybe you can really get this stuff moving fast toward the midpoint, but how do you stop at the destination?

    With onboard propulsion you would just flip the craft at the halfway mark, and fire the rocket (or whatever) in the other direction, but if this is using the momentum from Earth photons to go, I'm drawing a blank on how to decelerate. Do I have to .. *shudder* .. RTFA?

  • by weirdow ( 9298 ) on Thursday January 11, 2024 @11:18AM (#64149759) Homepage
    The aliens in the book also used a high energy laser to accelerate their spacecraft, which according to the humans ancient records made their star look red if I recall the book correctly
    • by ceoyoyo ( 59147 )

      Green. Their yellow star was in front of a red giant and when they fired their green laser it went from being a yellow mote in a red eye to a green one that outshone the giant.

      There's a sequel book, BTW.

  • 100 gigawatt laser array? Great Scott, for just 1.21% of that you could go back in time however far you need, launch a conventional probe, and come home just as the data starts to arrive. NASA, call me.
  • Aina nothin' we send gonna reach no 'nother star in a century. Nope.

    • We just lost a payload trying to get to the moon this week right after launch .... these guys really are thinking big.
  • Sounds like the premise behind Larry Niven's 1974 novel "The Mote in God's Eye."

  • Remarkable (and depressing) to consider that they're planning ahead to a time when I will likely be dead.

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