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Mars Space

Solar Super-Sail Could Reach Mars in a Month 499

ti-coune sent us a story running on newscientist describing solar super sails and how they could one day get us to Mars in a month. The key is a special new paint. The cast of Trading Spaces is unavailable for comment.
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Solar Super-Sail Could Reach Mars in a Month

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  • by numbski ( 515011 ) * <numbskiNO@SPAMhksilver.net> on Tuesday February 01, 2005 @11:01AM (#11540663) Homepage Journal
    I don't see any cast. [realityblurred.com]

    BTW. The sail emits carbon monoxide to get its speed boost. You know, the stuff the kills humans almost as fast as dihydrogen monoxide.

    You really want to be behind that thing for a whole month?
    • by the_mad_poster ( 640772 ) <shattoc@adelphia.com> on Tuesday February 01, 2005 @11:03AM (#11540681) Homepage Journal
      Yea, I imagine carbon monoxide poisoning is probably the biggest issue facing unprotected free-floating humans in space.
    • by Arimus ( 198136 ) on Tuesday February 01, 2005 @11:04AM (#11540709)
      You're in front of it - you'd be pushed along so it would make sense to put the sail at the back. I'd be more worried though about the effects if the craft turned unexpectedly and dropped your capsule into the microwave beam.
      • Re:Cast? What cast? (Score:3, Interesting)

        by TigerNut ( 718742 )
        ... Putting a sail at the back of a ship is like pushing on a rope, since the sail won't be rigid.
    • by Anonymous Custard ( 587661 ) on Tuesday February 01, 2005 @11:06AM (#11540745) Homepage Journal
      BTW. The sail emits carbon monoxide to get its speed boost. You know, the stuff the kills humans almost as fast as dihydrogen monoxide.

      You really want to be behind that thing for a whole month?


      Right, like they're going to be flying along to Mars with the windows open.
    • BTW. The sail emits carbon monoxide to get its speed boost. You know, the stuff the kills humans almost as fast as dihydrogen monoxide.

      I'll take that risk. I was never that good at breathing in outerspace anyways....
    • by numbski ( 515011 ) *
      TWO JOKES!

      I should be modded funny. Not interesting, and not troll. :P

      That was supposed to be funny. You're in a vaccuum. I almost mentioned something about Paige Davis and sex tapes, and STAYED ON TOPIC!!!!

      Come on mods, live a little. :P
    • Re:Cast? What cast? (Score:5, Interesting)

      by paranode ( 671698 ) on Tuesday February 01, 2005 @11:08AM (#11540769)
      The idea is actually pretty good, but the problem is the technology is not there to support it yet. The most notable obstacle from the article:

      "The feat would require a 60-megawatt microwave beam with a similar diameter to the sail. It would also have to be capable of tracking the craft as it accelerated away. But this power level could not be delivered by any existing microwave transmission system. The deep-space communications network that NASA uses to communicate with Mars rovers and the Cassini probe now orbiting Saturn can only manage half a megawatt. The Benfords say the power could be ramped up in future and hope to persuade NASA to consider doing this as part of a future upgrade to the network.

      So basically NASA's currently-used equipment is 1/120th of the power needed to get this sail to Mars. I would say this idea is not in our near future for sure.

      • Re:Cast? What cast? (Score:5, Informative)

        by Jonathan_S ( 25407 ) on Tuesday February 01, 2005 @11:40AM (#11541220)
        "The feat would require a 60-megawatt microwave beam with a similar diameter to the sail. It would also have to be capable of tracking the craft as it accelerated away. But this power level could not be delivered by any existing microwave transmission system. The deep-space communications network that NASA uses to communicate with Mars rovers and the Cassini probe now orbiting Saturn can only manage half a megawatt. The Benfords say the power could be ramped up in future and hope to persuade NASA to consider doing this as part of a future upgrade to the network.

        So basically NASA's currently-used equipment is 1/120th of the power needed to get this sail to Mars. I would say this idea is not in our near future for sure.
        Um, NASA's current communications system puts out 1/120th of the power needed for this sail.

        That's like saying since your cell phone can only put out 1/2 a watt it's impossible to heat things in your microwave.

        A couple of points of reference, the radar mounted on US Aegis cruisers can put out 4 MWs and the stationary Cobra Dane early warning radar that went online in 1977 puts out 15.4 MW.

        I don't think we are that far away from building a 60 MW transmitter now that we have a reason to.
        • Re:Cast? What cast? (Score:5, Informative)

          by Tassach ( 137772 ) on Tuesday February 01, 2005 @12:20PM (#11541693)
          A couple of points of reference, the radar mounted on US Aegis cruisers can put out 4 MWs and the stationary Cobra Dane early warning radar that went online in 1977 puts out 15.4 MW.

          I don't think we are that far away from building a 60 MW transmitter now that we have a reason to.

          Unfortunately, RADAR, like all other forms of non-coherent EM radiation, spreads out over distance. In order for this to work, you need to have the power actually hitting the sail, which basically means you're going to need a battery of MASERS which will still be sufficiently focused at 35 million miles to deliver most of their power to the sail. [wikipedia.org]
          • by Catbeller ( 118204 ) on Tuesday February 01, 2005 @12:42PM (#11541988) Homepage
            Nope. I believe they said that it would require ONE hour of focused microwave energy on the sail while still in low earth orbit to achieve Ludicrous Speed.
            Then it coasts.

            So, basically you build 20 2 MW transmitters and focus their output on a point a few hundred or thousand miles away -- I assume after an hour the craft will be moving away pretty damned quick, so a few thousand miles then.

            How does this thing STOP? You make Mars, but what's slowing it down from 150 miles per second so that it'll achieve orbit? Atmospheric braking? Um, no, let that go - no airbraking, it'd vaporize. Even if it could withstand a 150 mps entry without puffing out, it'd punch out of the atmosphere in seconds, with no time to kill much speed. No rockets either -- can't carry enough fuel to kill 150 mps.

            You'd need another microwave array in a high Martian orbit to fire at the solar sail as it came streaking in from Earth, if you want it to downspeed to make orbit. I'd assume the sail reverses somehow, so the craft comes in tail first.

            Now. If you want a FAST vehicle, build a solar powered multi-megawatt laser at an LaGrange point, and use the nicely focused red laser on a solar sail. The craft'll be at Mars in, what, two weeks?

            There's a couple of points that occur to me: the mass of the object being towed by the sail is irrelevant, mostly; you could tow the Sears Tower if you want. You'd just have to fire the lasers/microwaves for a longer time. A laser/purely reflective sail would be used for really heavy objects, and the gas-outing microwave system for smaller payloads, because the amount of paint on the sail is limited and will be exhausted, while a pure mirror-sail is static and can be used indefinitely.
            • Re:Cast? What cast? (Score:3, Interesting)

              by Tassach ( 137772 )

              I believe they said that it would require ONE hour of focused microwave energy on the sail while still in low earth orbit to achieve Ludicrous Speed.

              I should have RTFA first :-) You're right.

              How does this thing STOP?

              Good question. Off the top of my head, I'd say you'd slingshot around Mars so you're headed back twords the sun and use the sun (or, as you suggest, a laser in Earth orbit) to decellerate enough to get into orbit around Mars. I don't know how long it would take to decellerate with a

    • Re:Cast? What cast? (Score:5, Informative)

      by GileadGreene ( 539584 ) on Tuesday February 01, 2005 @11:44AM (#11541271) Homepage
      The sail emits carbon monoxide to get its speed boost. You know, the stuff the kills humans almost as fast as dihydrogen monoxide.

      Actually, if you RTFA you'll see that they discovered the effect as a result of inadvertently boiling off carbon monoxide, but the paint that the article is about would actually use something like hydrogen (or perhaps methane).

      You know, the stuff that burns much faster than dihydrogen monoxide ;)

    • by Supercarps ( 855375 ) on Tuesday February 01, 2005 @12:36PM (#11541910)
      Warning: Not for terrestrial escape. Solar sail for outdoor use only. Do not deploy in poorly ventilated regions of space. Emissions sticker must be displayed on windshield of personnel module at all times. Solar System law prohibits tampering with or disabling of solar sail emission control systems. (Additional requirements apply above Earth's California.) It is illegal to use 60 MW microwave source in any manner inconsistent with labeling (e.g. popcorn, "phone home", mind control of homeless.) Not safe for children under 6 (toxic if eaten, asphyxiation hazard). May be fatal if used as shelter in bright sunlight or under lightning conditions. Improper disposal threatens wildlife and environment - ask local authorities about stellar propulsion system recycling programs.

      "Yeah, they found the poor bastard in his space garage with the door closed and the solar sail running. Damn shame."
  • by Anonymous Coward on Tuesday February 01, 2005 @11:02AM (#11540672)
    The invention of a warp drive or time machine could get us there immediately. Weather at 10.
  • by Uncle Eazy ( 671354 ) on Tuesday February 01, 2005 @11:02AM (#11540673) Homepage
    The cast of Trading Spaces is unavailable for comment. TSIA.
  • Fuel (Score:5, Interesting)

    by MyLongNickName ( 822545 ) on Tuesday February 01, 2005 @11:03AM (#11540689) Journal
    It is very cost benefitial to not have to take fuel with you... or at least not as much.

    My question is, what kind of payload is practical with this kind of thing? I've always read that to get any kind of larger payload, you cannot use solar sails. Do they get around this by using the microwave beam they talked about (ie higher energy per square meter)? I wish there were more numbers in the article...
    • Re:Fuel (Score:5, Insightful)

      by will_die ( 586523 ) on Tuesday February 01, 2005 @11:14AM (#11540850) Homepage
      Once you get it into inital orbit payload weight would not be a problem, size would matter size it could not block the sails. Whatever the payload is I hope that you don't mind it smashing into the planet. They don't discuss slowing down or landing.
      Going at 60 kilometres per second it is going to take a good amount of fuel and time to slow that thing down.
      • Re:Fuel (Score:4, Insightful)

        by clausiam ( 609879 ) on Tuesday February 01, 2005 @11:50AM (#11541345)
        Once you get it into inital orbit payload weight would not be a problem
        2 words - Mass and Momentum. Sure the payload matters. Size wouldn't matter as the payload carrying part would be facing away from earth and would need to be protected from 6MW of microwawes anyway.
      • Re:Fuel (Score:5, Interesting)

        by ThosLives ( 686517 ) on Tuesday February 01, 2005 @12:39PM (#11541943) Journal
        Indeed. 60 kps is way past escape velocity for the solar system; from Earth mean orbit, solar escape velocity is only 42kps (give or take)!

        Incidentally, I want to see their 60 kps calculation ... that's a huge momentum change over an hour! The average acceleration for 60000 m/s in 3600 seconds is: ~16.7 m/s2. I don't know about you, but methinks they got a decimal point wrong. Or their entire ship was made of aerogel and has very little mass...

        Here's some fun math: 60 MW of (1mm/300GHz) microwaves will carry a momentum of 0.2 N; if the sail absorbs all of the photons, the force would be 0.2 N; if it reflects them completely the force would be 0.4 N. To get an acceleration of 16.7 m/s2 you need a force of 16.7 N per kilogram. All this says is that they're getting a lot of force from breaking the chemical bonds in the paint. Kind of like burning fuel.

        Show my work: Energy per photon is h*f where h is plank's constant and f is the frequency. For 300 GHz microwaves, f = 3e11 Hz and h is always 6.626e-34 J.s; each photon has ~2e-22 J. 60 MW means you have ~3e29 photons per second. Momentum per photon is p = h/w, where w is the wavelength (1e-3 m), so each photon has a momentum of ~6.6e-31 N.s. 3e29 photons per second of 1 mm microwaves have a momentum flux of 0.2 N.

    • Re:Fuel (Score:5, Funny)

      by nine-times ( 778537 ) <nine.times@gmail.com> on Tuesday February 01, 2005 @11:15AM (#11540873) Homepage
      Yeah, numbers would be nice to know, for example, how big the sail would need to be. I sure hope this picture [newscientist.com] isn't supposed to be to scale.
      • If it is, then Earth is about 250Km diameter.
      • Re:Fuel (Score:3, Funny)

        by drew ( 2081 )
        if it is to scale, then mars is really only about 900 km away- so taking a month to get there with this new technology wouldn't be very impressive, considering i can drive 900km in about 8-9 hours
  • Then what? (Score:5, Interesting)

    by FroBugg ( 24957 ) on Tuesday February 01, 2005 @11:04AM (#11540691) Homepage
    So you're going faster than any interplanetary craft to date, and your only propulsion system requires you to be moving away from the sun (or the Earth, if they're using a laser to push you).

    How do you slow down? Orbital insertion at that speed would be seriously difficult, if not impossible.
    • by R0UTE ( 807673 )
      They didnt mention that everyone on the craft had to blow really hard in the opposite direction when they started getting near to slow them down?
    • Re:Then what? (Score:3, Interesting)

      Solar sails have been proposed that have a mirror system to allow the other half of the said to get the energy. At the half way point (more or less), the system basically reverses itself, causing a slow down. I assume a similar method would be used here.
    • Re:Then what? (Score:5, Informative)

      by merlin_jim ( 302773 ) <James@McCracken.stratapult@com> on Tuesday February 01, 2005 @11:12AM (#11540825)
      So you're going faster than any interplanetary craft to date, and your only propulsion system requires you to be moving away from the sun (or the Earth, if they're using a laser to push you)

      As I've previously discussed on slashdot, you do not need to be moving outward from your energy source in a solar sail, you can achieve thrust vectors in any direction from full away to orthogonal (perpendicular for the 2D vector peeps)

      And orbital mechanics isn't of the form of "thrust straight at where you want to go" it's more like "thrust in the direction of orbit to move away from primary, thrust against the direction of orbit to move towards primary"

      The only time a solar sail would even find it efficient to thrust directly away from the inner solar system is if it was an interstellar sail, after it reached escape velocity... before then thrust away from the primary doesn't change the mean orbit distance, it changes the eccentricity of the orbit.
    • Airobreaking (Score:3, Informative)

      by essreenim ( 647659 )
      1. Airobreaking.

      This is where a craft uses the planets atmosphere to dramatically reduce speed using friction. Its actually been used for decade but never on this large a scale..!! Later on

      2. Slowing down sufficiently with a Mars based system similar to the one on earth.

      OR

      3. A series of mirors which are swung into position at the right time to begin deceleration which reflect the light onto a surface pointing the opposite direction from source of beams..

    • Re:Then what? (Score:3, Interesting)

      by Sheepdot ( 211478 )
      > How do you slow down? Orbital insertion at that speed would be seriously difficult, if not impossible.

      There's a million comments already along these lines. Isn't it obvious? You cut the lines. Then you can use any type of propulsion system to slow down before impact. Just like they use similar ways of slowing down with probes right now.

      Think of it as a reverse parachute. You cut the line and then burn through your fuel to actually slow down. You don't want to cut the line too late obviously, but you
    • Most likely, you build another microwave assembly on Mars using other means.

      Then you just switch from the one microwave beam to the other when you want to slow down.

    • by CmdrGravy ( 645153 ) on Tuesday February 01, 2005 @11:51AM (#11541360) Homepage
      They would drop the solar anchor
    • Getting back (Score:2, Insightful)

      by nairolF ( 315683 )
      I think the term "solar sail" is a bit of a misnomer here. If I understood correctly, almost all the thrust comes from the recoil of particles boiling off the surface, because the surface is heated by a microwave beam. This thrust is therefore perpendicular to the surface of the "sail", which is (largely) independent of the direction towards the microwave source. The exception is that, if the sail is parallel to the beam, then the microwaves don't hit the sail at all, and the system doesn't work.

      But it w
    • Remeber, both Mars and Earth are going around the sun. You aren't sending it in a straight line. You are actually pushing it out to a "higher" orbit to intercept with Mars. To bring it back, simply change the angle (vector of force) and push it to a "lower" orbit. Plain 'ol high school physics here.

      - higher means further from the sun and lower means closer.
  • Wow.. cool! (Score:2, Interesting)

    by chris09876 ( 643289 )
    "The Benfords calculate a one-hour burst of microwaves could accelerate the craft to 60 kilometres per second" That's quite fast... :) With the trip only taking a month, I'd imagine it would make it much more manageable for whoever made the journey.

    Although it may not be the most practical thing in the world, having people visit Mars gets me excited. It's just like something out of TV shows
  • by Viol8 ( 599362 ) on Tuesday February 01, 2005 @11:04AM (#11540701) Homepage
    Or get back to earth for that matter? Nice idea as long as you don't mind a one way trip into deep space.
    • Solved years ago by Robert Forward in The Flight of the Dragonfly [amazon.com], a novel with a large appendix describing an interstellar craft using a laser pumped solar sail... and it decelerates and can come back.
    • by Angstroem ( 692547 ) on Tuesday February 01, 2005 @11:18AM (#11540907)
      Slow down: Rocket thrusters (mainly for maneuvering) and athmosphere.

      Coming back: Send robotic missions do deliver necessary parts and prefabricated modules, then send human heroes to put everything together. If some part fails, they at least are heroes.

      Mind you, exploration never included the guarantee of a safe way back. It always took some people to take the risk of losing their lives.

      Because you can now safely travel over the Pacific Ocean in 5 hours doesn't mean it always was like that.

      • Not sure why that was modded insightful.

        If you could carry enough rocket power to stop that speed, you could carry enough rocket power to build up that speed, and we wouldn't need exotic ground-based propulsion systems.

        You can't use rockets to stop. In fact, the suggestion that you could use another array at Mars to stop seems unlikely because of the unlikely possibility that you could vaporize just the paint on the back side of the sail, and not cause the heat to vaporize the bottom layer of paint on the
    • Simple. Cut the strings. I think it goes without saying that they'll have to use rocket propulsion to get back, though. At least, until they get another microwave beam at the Mars end.

      http://science.howstuffworks.com/solar-sail.htm
    • Or get back to earth for that matter?

      Well, it slows down with retro rockets. :-)

      In my humble opinion it would probably be better to send a couple of dozen humans to Mars on a one way trip the first time around so they can start building a colony. It's just to far to think about a short hop return mission.

      This will never happen, the budget will have been cut so much by the time we get around to sending humans to mars it'll be a couple of guys spending a couple of weeks there with minimal scientific expe
  • by ArsSineArtificio ( 150115 ) on Tuesday February 01, 2005 @11:04AM (#11540708) Homepage
    The cast of Trading Spaces is unavailable for comment.

    Did you even bother to ask them?
  • by FreeUser ( 11483 ) on Tuesday February 01, 2005 @11:05AM (#11540719)
    From TFA:
    Gregory Benford of the University of California, Irvine, and his brother James, who runs aerospace research firm Microwave Sciences in Lafayette, California, envisage beaming microwave energy up from Earth to boil off volatile molecules from a specially formulated paint applied to the sail. The recoil of the molecules as they streamed off the sail would give it a significant kick that would help the craft on its way.


    Why does this seem incredibly wasteful of energy?

    Wouldn't it be far wiser to build solar panels in orbit, use them to power Microwaves, and avoid the attenuation in the atmosphere? This would have the added advantage of not draining power from the Earth to power the spacecraft: we would get our power from the Sun and pipe it directly to the spacecraft as Microwaves, without involving the planet at all (except, of course, as controlling entity).
    • by revscat ( 35618 ) on Tuesday February 01, 2005 @11:15AM (#11540869) Journal

      Wouldn't it be far wiser to build solar panels in orbit, use them to power Microwaves, and avoid the attenuation in the atmosphere?

      Well, from TFA:

      The feat would require a 60-megawatt microwave beam with a similar diameter to the sail.

      Now, I'm no EE, so somebody please correct me if I'm wrong, but I'm thinking that generating that much power from solar cells would be an undertaking in and of itself. You'd be hard pressed to generate that much energy in space.

      • We can generate 60-megawatts is space. It would just involve putting a nuclear reactor in space.
        • We can generate 60-megawatts i[n] space. It would just involve putting a nuclear reactor in space.

          It could be done with solar power. Of course, full spectrum vacuum solar in earth orbit is about 1.3 kW/m^2; so, for 60000 kW, you need a minimum of 45000 m^2 of solar collection area. Since conversion efficiency tends to be about 30% at best, 135000 m^2 is more realistic-- ballpark a dozen football fields worth.

          Using that area for reflectors to concentrate down to smaller power cell areas might reduce cos

          • Flipside is, instead of putting a single 60 MW reactor, we put several smaller ones in orbit. We have already made reactors that can survive their rocket being blown up (as in without spreading any nuclear material around) so that is no problem.
      • by saigon_from_europe ( 741782 ) on Tuesday February 01, 2005 @11:50AM (#11541349)
        Now, I'm no EE, so somebody please correct me if I'm wrong, but I'm thinking that generating that much power from solar cells would be an undertaking in and of itself. You'd be hard pressed to generate that much energy in space.
        It seems feasable.

        I am EE, but I don't know what is the value of Sun's radiation. IIRC, it is about 400W/m^2 on Earth, so it is in worst case the same in orbit. With cell's efficiency of 25%, we get about 100W/m2, so for 60,000,000W we need only 600,000m2. It is sqare with side of 775m - not something too complicated to build even on our current technological level.
    • TFA seems slowed by slashdoting at the moment (and I'm on dialup), but I would guess that putting the kind of emmiter in orbit that could provide that kind of output would be prohibitively expensive. We have a power grid here on earth already, why not use it to send the microwaves up and simply live with the reduced efficiency? I imagine that the cost of the extra energy would balance out the savings from not launching the microwave emmiter into orbit.

      On the other hand, if we could build a solar array +
    • Take a look at this article [spacefuture.com] for way too much information about orbital solar power.

      Basically microwaves can be transmitted through the atmosphere without too much trouble, while building stuff in orbit is incredibly expensive. It might be possible to create an orbital relay station to deal with issues like focus, assuming that's a problem.
    • Why does this seem incredibly wasteful of energy?

      I don't know. Why should it seem wasteful? Ground-based energy is incredibly cheap after all.

      Let's see. Assuming very conservatively that only 1% of the power ends up illuminating the craft. That's 6 GW for an hour. Given 10 cents per KwH, that's a cost of $600,000.

    • by Waffle Iron ( 339739 ) on Tuesday February 01, 2005 @12:06PM (#11541529)
      Why does this seem incredibly wasteful of energy?

      Wouldn't it be far wiser to build solar panels in orbit, use them to power Microwaves, and avoid the attenuation in the atmosphere?

      Talk about penny wise, pound foolish. A 60 MW solar power station in orbit would be far larger than the International Space Station. It cost dozens of $Billions just to launch the space station; designing, launching and maintaining a 60MW station would probably cost hundreds of $Billions.

      When you spend money on something, you're allocating a certain fraction of the economy towards a that purpose. That comes with a roughly similar fraction of the world's energy consumption. Dedicating huge teams of people designing, building and launching an orbital power platform will consume a commensurate amount of energy down here on this planet as they go about their tasks. Building the station and the massive rockets to launch it will consume vast energy resources before it even gets off the ground; vastly more energy than the station could ever produce.

      For example, assume the station costs $100 Billion. That's about 1% of one year of the ~$10 Trillion US economy. The US consumes about 1e20 joules of energy per year, so if the money spent on the station is associated with a proportional amount of energy, that's 1e18 joules. That's more power than a 60MW power plant would produce in 500 years.

  • Then? (Score:2, Insightful)

    by intercodes ( 819880 )
    powered by a solar sail get from Earth to Mars in just one month

    Then what....!?
  • "Don't settle for pale memories. Don't go for fake implants. Instead, travel on a real live vacation you can afford!"
  • Microwave Lens (Score:3, Interesting)

    by Dana P'Simer ( 530866 ) * <dana...psimer@@@dhptech...com> on Tuesday February 01, 2005 @11:05AM (#11540732) Journal
    If they could find a way to reflect or refract microwave radiation from the sun they could use a space based "microwave lens" to get the 60MW microwave beam. Probably would have to be a pretty big lense.
  • by Faust7 ( 314817 ) on Tuesday February 01, 2005 @11:06AM (#11540737) Homepage
    "Emergency channel, zero-one-three-zero, Code Red. It has been three hours since our contact with the alien probe. All attempts at regaining power have failed. All non-essential fuel has been given...to slow our consumption of life-support reserves. Our chief engineer is trying to deploy a makeshift solar sail. We have high hopes that this will, if successful, generate power to keep us alive."
    • Emergency channel, zero-one-three-zero, Code Red. It has been three hours since our contact with the alien probe. All attempts at regaining power have failed. All non-essential fuel has been given...to slow our consumption of life-support reserves. Our chief engineer is trying to deploy a makeshift solar sail. We have high hopes that this will, if successful, generate power to keep us alive. /offtopic Ah yes... ST:IV... You know, I think that guy, and Engineer Singh in ST:TNG who died when that weird elect
  • BTW. The sail emits carbon monoxide to get its speed boost. You know, the stuff the kills humans almost as fast as dihydrogen monoxide. You really want to be behind that thing for a whole month?

    Do you really think that they haven't thought about that? First of all, the astronauts would be in some sort of pressurized cabin that will take care of all their air-breathing needs. I'm pretty sure they wouldn't let the CO from outside get in. Furthermore, the pressure inside will be much greater than the pressure outside. Hence air will have a tendency to flow out, rather than the CO flowing in.
  • I think it would be kind of neat to go back to the "sail" days. Sort of like that one star trek movie - where there was the big sail device that would suck up the energy of the planet - except this one is used for something beneficial :D
  • Holes in the sail? (Score:4, Interesting)

    by vivin ( 671928 ) <vivin.paliath@nOsPam.gmail.com> on Tuesday February 01, 2005 @11:11AM (#11540806) Homepage Journal
    leaving a micrometre-thin sail to continue the voyage to Mars.

    I wonder how susceptible this sail would be to space dust, meteorites and space junk? Also, in response to an earlier comment made by someone about CO, I believe this technology would be used to send PROBES mostly and not people to Mars. Think about it... if they sent a person out there, how would they get back? They would need to use conventional means, which would defeat the whole purpose. Unless of course, they had another sail, AND a microwave transmitter on Mars.

    This technology will be good for sending probes, but not for sending people, just yet.
    • by merlin_jim ( 302773 ) <James@McCracken.stratapult@com> on Tuesday February 01, 2005 @11:19AM (#11540926)
      I wonder how susceptible this sail would be to space dust, meteorites and space junk?

      Not that susceptible. You design it to tear on impact, leaving an impact hole only marginally larger than the impact object.

      This sail isn't like a wind sail; wind sails work off of a pressurized fluid, which will tend to flow through holes and tears, meaning even a small tear can greatly effect efficiency.

      This sail works off of photon pressure, which does not flow like a fluid, so a small hole means you only lose thrust in proportion to the area of the hole...
  • Since Gregory Benford is also a scifi author, I expect to see this in a book soon.

    I don't expect to see it in reality anytime, though, due to the basic problems with a one-way propulsion system. How do they decelerate when they arrive? There won't be anybody waiting for them at Mars with a laser pointed the other way, after all.

  • 60 MW ... (Score:4, Funny)

    by matth1jd ( 823437 ) on Tuesday February 01, 2005 @11:11AM (#11540816)
    at least it's not 1.21 Gigawatts...
  • by Gorath99 ( 746654 ) on Tuesday February 01, 2005 @11:14AM (#11540852)
    Not an astronomer or space engineer, but does this one month timeframe take the required slowing down into account? You can't just point a spaceship at something, shoot it away at 60 km/s and expect it to both stop at its destination and survive arrival.

    And while we're at it: how does one slow down a craft like this? Without destroying it or tugging along a rediculous amount of fuel, that is.
  • It's crazy, you know.

    But it just might work.

  • In case you didn't notice it, it would appear that the Gregory Benford cited in the article is the same Gregory Benford who writes some very good hard sci-fi.

    People like Benford who do many things well are inspiring.

    Now, go check out the Galactic Center series. (Someone else can find the link to Amazon, Barnes and Noble, or your local book seller.)

    -Peter
  • by Ancient_Hacker ( 751168 ) on Tuesday February 01, 2005 @11:54AM (#11541392)
    One of their minor obstacles is going to be finding some way of heating up their reaction mass to fantastic temperatures while not simultaneously heating whatever is containing it. And forget about nano-tech. The basic laws of scale are working really hard against them. The volume being heated is miniscule, while the surface area is much larger in proportion, so it's effectively impossible to heat anything very small. Think of the smallest flame you've ever seen. You just can't make them any smaller.
  • What about putting the microwave transmitter on the moon? You could cover the whole light side with solar panels to charge the system up. Maybe even put up a nuclear reactor or something...

    Just a thought...
  • This reminds me of a 70s project to develop a plastic rifle stock for use by Nato forces. It was found that a laser hit on the stock could generate enough toxic gas from chemical decomposition of the surface to kill or incapacitate a sniper in the usual firing position. The composition was hastily rethought...I think the gas produced was a cyanide or isocyanide rather than carbon monoxide, but technology once again shows an ability to return in a different way.

    Pity they couldn't have got those rifle stocks

  • Wow. Count Dukoo can really make a fast getaway in that.
  • by JavaRob ( 28971 ) on Tuesday February 01, 2005 @12:10PM (#11541577) Homepage Journal
    The key is a special new paint...

    The "ricers" were right!

    And all this time, I thought that inane changes to your vehicle to make it *look* faster wouldn't actually do anything for the performance.

    Boy, was I wrong.
  • by ninjagin ( 631183 ) on Tuesday February 01, 2005 @12:16PM (#11541646)
    ... a solar sail if you're beaming microwaves at a film with a coating that releases a gas, right?

    For some reason I thought that solar sails captured photon pressure to accelerate an object by very very teeny tiny amounts over a long period of time.

    As I read the article, they're still using the idea of a sail, but the acceleration comes from the release of gas. So isn't this a "gas sail"?

    If it is a gas sail, then don't you have to worry about holes in the sail fabric/material? You're back to fluid pressure on a sail surface, aren't you?

    It seems (admittedly, in my own uneducated, poorly-informed estimation) like the "gas sail" material would have to be more robust than with a solar sail.

    Can someone clarify for me?

  • by mapmaker ( 140036 ) on Tuesday February 01, 2005 @12:26PM (#11541781)
    The key is a special new paint.

    Let me guess - a flame job on the hood to make it go faster.

    Slap a whale tail on the trunk and a chrome tailpipe out the back and you could get to Mars in a week!

  • by Dr. Zowie ( 109983 ) <slashdot.deforest@org> on Tuesday February 01, 2005 @12:41PM (#11541973)
    The sail is being used as a rocket engine. That is not too helpful, as the exhaust speed of the paint is still limited by chemical bonds (it's hard to make individual paint molecules leave with more kinetic energy than is contained in a chemical bond). That means you would need just as much propellant (in the form of paint) for this scheme as you would need for a normal chemical rocket engine.

    These guys are definitely on an interesting track, though. The problem with rocket engines in general is that they have a tradeoff between mass efficiency (you want to put as much momentum on each piece your propellant as possible, so that you get as much push from it as possible) and energy efficiency (it costs energy to push propellant, and you have to supply the energy).

    Chemical rockets can't get much more efficient than the Space Shuttle Main Engines, because the amount of energy available for each molecule of exhaust gas is whatever you can get by chemically reacting your fuel to make the propellant molecule. The SSMEs use one of the most energetic-per-unit-mass chemical reactions around: hydrogen and oxygen (fuels) combining to make water (propellant).

    Electric ion rockets do better because each molecule of propellant gets much more energy than would be available from chemical reactions. The problem there is that you still have to produce the energy. Nuclear electric propulsion uses plutonium to generate heat, which is converted to electricity and then used to run the ion rocket. Solar electric propulsion uses solar panels to generate electricity that runs the ion rocket. The problem is that both of those schemes are limited by the power available: it's hard to make energy rapidly with either a conventional radiothermal (noncritical) generator or solar panels, so while the rocket is extremely fuel efficient it is also quite slow.

    Pure solar sails use the best/worst propellant in the Universe: photons. Best, because photons are disposable -- "use all you want, we'll make more!". Worst, because photons use the most energy per unit delivered momentum of any propellant in the universe. So a sail transduces huge amounts of power (at least in the inner solar system) but uses a very inefficient process to convert that energy to momentum.

    Making the sail into a hybrid rocket is a Good thing, but using this paint scheme doesn't help, because the ejected molecules don't ever get much more energy than their own chemical binding energy into the paint -- that means they're being more or less wasted as propellant, because you want to put as much kinetic energy on the propellant as possible.

    A better scheme is to use a curved solar sail as a concentrator to heat up a high power electrical generator, and then use the electricity to drive an ion rocket. In 2000 or 2001 I and a colleague worked up the numbers for such a scheme (there are technical problems with making high-power ion rockets; but we considered just energy flow). A smallish curved solar sail (say, 120m in diameter) can concentrate 10 megawatts of heat onto a heat collector. At 10% conversion efficiency to propellant power (15% for conversion to electricity, times 67% efficiency in the rocket engine) that would still be a megawatt of power, enough to provide hundreds or thousands of Newtons of thrust. In several scenarios we considered, the acceleration of the whole craft is higher than the unloaded self-acceleration of the sail, so it would be necessary to repel the sail electrostatically or something like that to keep its shape correct.

    Ion rockets can be 100 to 1000 times more propellant-efficient than chemical rockets, provided that there is enough energy available.

  • by xutopia ( 469129 ) on Tuesday February 01, 2005 @01:20PM (#11542465) Homepage
    *could*
  • by Hank the Lion ( 47086 ) on Tuesday February 01, 2005 @02:23PM (#11543177) Journal
    Simple energy calculation:
    1/2*m*v^2=P*t.
    P=60MW, t=3600s, v=60km/s.
    At an efficiency of 100%(!), the maximum mass you can give this speed is 120kg.
    The sail will be 100m across, this is 10,000 m2.
    The maximum mass per square meter, including structural integrity (there will be quite a bit of force on the sail to make it accelerate to 60 km/s in just one hour, about 2000N!) is 12g/m2.
    Then, I think, you will want to have some payload to reach Mars to do the actual experiments with... This needs to be subtracted from the mass of the sail.

    OK, some of the mass of the sail will evaporate to enhance propulsion, so acceleration at the end (when the construction is lighter) will be higher than in the beginning, but a lage part of the energy will be taken away by the evaporating gas as well, so efficiency will be quite abit lower than 100%.

    All in all, how do they think to make this construction?

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