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Toys Science

Tokyo University's "Microwave Rocket" 48

LiftOp writes "Apparently a group from Tokyo University's Department of Advanced Energy has used a high-power microwave beam to heat the air beneath a model rocket , sending it skyward (well, two meters). Dr. Kimiya Komurasaki, who led the group, seems to be quite a directed energy buff; when the rocket eventually gets beyond the air level, a conventional motor could be used to send it further."
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Tokyo University's "Microwave Rocket"

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  • high energy ? (Score:3, Interesting)

    by ddd2k ( 585046 ) on Tuesday April 15, 2003 @12:17AM (#5733701) Homepage
    Correct me if i'm wrong, but doesn't using microwave radiation to heat the air consume a lot of energy than burning solid fuel? If so, wheres the applicable purpose?
    • Re:high energy ? (Score:5, Informative)

      by clambake ( 37702 ) on Tuesday April 15, 2003 @01:31AM (#5734032) Homepage
      Ah, well the point of it is simple. A rocket normally requires a LOT of lift of energy precisely because it needs to lug tons and tons of fuel up with it as it moves a long. By dropping those fuel-pounds, or at least some of them, you can carry a lot more stuff... More stuff into space is a Good Thing.
      • Yes, but even having 10x more fuel still only costs 1% of the cost of the rocket. So you need bigger engines to carry the fuel up- but the thrust:weight ratio of rocket engines are typically 100:1, so one hundred tonnes of fuel is carried by 1 tonne of engines.

        And because the dry mass of the rocket is the expensive bit, you haven't pushed up the cost of the vehicle by much.

        And air is actually a much worse propellent than rocket fuel; you need many times more energy than the better rocket fuels to get the

      • What about making a jet out of the same technology? A rocket requires pretty tremendous amounts of thrust, and the air thins out at higher altitudes. I could see the need for a compressor to ensure that there is enough air to heat; otherwise, it would lose power in the upper stratosphere. I like the idea of of electrical energy. Now all they need is a smaller nuclear power plant, and you could have a plane that flies forever. Apparently, there were some nuclear powered airplane experiments back in the 1950
    • Re:high energy ? (Score:5, Insightful)

      by QuantumFTL ( 197300 ) on Tuesday April 15, 2003 @02:47AM (#5734193)
      Correct me if i'm wrong, but doesn't using microwave radiation to heat the air consume a lot of energy than burning solid fuel?

      Yes, I would imagine it does.

      If so, wheres the applicable purpose?

      Unfortunately when building a rocket to go into space, most of the fuel is spent CARRYING FUEL UP. That's just plain uneconomical. So when one is only lifting the actual payload (and perhaps some small reflector or whatever) there's a *HUGE* energy savings.

      There's also the issue of reliability/stress. Things which are being thrown into orbit at high velocities have to be engineered very well to survive the trip. Mass must be shaved, redundancies might be cut to lower costs, etc. Building things on the ground is much easier in these respects... redundancy is much less limited, much less stress is on teh equipment, it's much easier to diagnose repair (because it doesn't have to be all micro-sized, etc). Also miniturizing things can considerably inflate their cost. So keeping as much of the equipment on the ground as you can is a good idea.

      There's also safety issues... Most rockets use very dangerous explosive fuels, some of which are environmentally unfriendly. As long as a poor bird doesn't stray into the beam, this should be able as environmentally friendly as possible.

      One last answer is that it allows most of the launch system to be reused between launches... Disposable rockets can't do this, and the Space Shuttle doesn't even re-use that much of it's mass... just some of the more complicated bits.

      There are of course downsides to this technique (what if the spacecraft drifts off the beam, or the beam is obscured, etc) however I believe that they will eventually be overweighed by the enormous benefits.

      It's a good question and not all the answers are obvious. I can't wait for the day where most of the work launching stuff into space is done from the ground.

      Cheers,
      Justin

      Warning: I am not a physicist yet, but I almost have my degree. I also work at the Jet Propulsion Lab :-)
      • Re:high energy ? (Score:3, Insightful)

        by dschuetz ( 10924 )
        There are of course downsides to this technique (what if the spacecraft drifts off the beam)

        From a great special-issue Scientific American a few years back, I think I have an answer for this.

        Some of the "heated air" approaches (using microwaves or lasers) depend on a convex reflective surface under the spacecraft, which focuses the energy just below it. If the spacecraft tilts, or drifts to the side, the light from the laser, hitting the underside, gets reflected in a slightly different place. In fact,
        • Concave surfaces. Convex mirrors won't focus
        • Re:high energy ? (Score:3, Informative)

          by QuantumFTL ( 197300 )
          Me: There are of course downsides to this technique (what if the spacecraft drifts off the beam)

          Reply: If the spacecraft tilts, or drifts to the side, the light from the laser, hitting the underside, gets reflected in a slightly different place. In fact, the simple geometry of the craft's underbelly guarantees that the focal point shifts just enough, in the same direction as the drift, that the next energy burst will nudge the spacecraft back onto the beam. So it's sort of self-correcting.

          Of course
    • I think the microwave energy goes throug the air without much heating. When it hits the rocket it is bundled and at the focal point of the radiation the field strenght is so high the air at that point ionizes and the energy of the microwave is dissipated there as heat. The expansion of the heated air propulses the rocket.
    • Well, one cool thing is that we would be able to launch rockets without using any fuel that we can't find more of. Billions of joules of sunlight pour onto the Earth every day. We just have to collect it and find a way to use it.

      This as opposed to fossil fuels, which take quite a bit of time to produce. They are far more efficent than most forms of energy storage, but they are very hard to make, and therefore, not easily renewable. Of course, the sun will eventually burn out, but we might as well grab
  • Footfall (Score:2, Interesting)

    by mattsucks ( 541950 )
    Reminds me of the book "Footfall", by Larry Niven and Jerry Pournelle. The climax of that book has a space vessel launched with atomic bomb explosions as the propulsive force. check it out [amazon.com].
    • Re:Footfall (Score:1, Interesting)

      by Anonymous Coward
      Man, that I lived to be old enough to snap at this....

      Google for the Orion Project - 50's concept of using atomic explosions to lift spacecraft
    • The idea of nuclear pulsed propulsion goes all the way back to Stanislaw Ulam in the 1950's. An investigation into the idea was called Project Orion and was headed by Freeman Dyson. One brief writeup can be found here [spacedaily.com].
  • by Oriumpor ( 446718 ) on Tuesday April 15, 2003 @12:54AM (#5733876) Homepage Journal
    Am I not correct in assuming that someone fired either a laser or a microwave beam at an object on a tether that looked similarly conical as this object, and made it move (In a lab mind you, horizontally, on a string... but I thought the concept was proven already.)

    The only problem was the projected G Forces were just too much for the human body, from what I remember.
    • Leik Myrabo (Score:3, Informative)

      by krysith ( 648105 )
      Leik Myrabo has been working on beam powered rockets etc. for years. "The Future of Flight" was published in 1985. He has done more work in this area than NEone else on the planet. He is currently working for RPI. Links: http://www.rpi.edu/dept/mane/deptweb/faculty/memb e r/myrabo.html http://www.lightcrafttechnologies.com/technology.h tml (I apologize if the urls dont come out properly. Slashdot formatting is still an arcane science to a newbie like myself. Dammit, Jim, I'm a physicist, not a webmas
      • do <a href="http://...">click here </a>
        • Thanks JohnFluxx. Let's try that again:
          click here [rpi.edu]
          click here [lightcraft...logies.com]
          And BTW, this ~is~ the laser powered rocket n1ywb mentioned below. Myrabo pops up on the Discovery channel every couple of years. Unfortunately, his progress has been fairly slow. I read his book back when I was in Junior High. His big problem is using lasers. Both lasers and microwaves have their problems. I think it is a good idea, though, and I wish Dr. Myrabo luck. I recommend the book to NEone who is seriously interested in
    • Laser powered rocket (Score:4, Informative)

      by n1ywb ( 555767 ) on Tuesday April 15, 2003 @08:39AM (#5735233) Homepage Journal
      This microwave rocket sounds totally pussy compared to the frikkin LASER powered rocket [optics.org] I saw on Discovery (or was it TLC? I never watch TLC anymore since it's all Trading Spaces now.)

      Anyway the laser "rocket" is actually a very lightweight aluminum puck about a foot in diameter, with a some funky curves. They shoot high powered laser pulses up its ass and that superheats the air underneith it, the expansion of which propells the rocket upwards. The pulses fire at about 500Hz so the damn thing sounds like a pulsejet. But at last check it reached an altitude of 71 meters and a flight time of 12.7 seconds. Microwave rocket eat your heart out! :)
    • If you're referring to the SciAm article on these things a few years back, I don't recall anything about excessive G-force.
      I believe the problem they had there was the lack of a suitably powerful laser. They were using C02 lasers in the SciAm tests I believe.
      What I wonder is if the deuterium flouride lasers the military has suggested for the MIRACL program would be of use. It seems that the problem with those was that they took a long time to recharge after lasing so perhaps not.
      Probabl
  • by clambake ( 37702 ) on Tuesday April 15, 2003 @01:34AM (#5734038) Homepage
    That one is easy, fresh popcorn for the onlookers!
  • Rocket Equation (Score:5, Informative)

    by Michael.Forman ( 169981 ) on Tuesday April 15, 2003 @01:49AM (#5734073) Homepage Journal

    A propulsion system such as this can provide a tremendous reduction in required energy.

    Conventional rockets, which carry their own fuel are large consumers of energy, as not only must they lift a payload into space but all the fuel as well. The total weight of a rocket including fuel is given by an exponential function known as the rocket equation. Stated simply, a rocket of mass m0 requires fuel of mass m1 to lift it; that fuel of mass m1 requires more fuel of mass m2 to lift it; the fuel of mass m2 requires fuel of mass m3; and so on, ad infinitum. The rocket equation is given by

    m = m0 exp(Vf/Vex)

    where m is the total required mass, m0 is the mass of the payload, Vf is the final velocity, and Vex is the exhaust velocity of the combusting fuel.

    This exponential increase in initial mass can be huge. For example a low earth orbit requires a change in velocity, Vf, of about 8 km/s. Kerosine and liquid oxygen provide an exhaust velocity of about 2.5 km/s. Thus, m/m0 = exp(Vf/Vex) = 24.5. It would take 25 times the original weight of a given payload mostly in fuel to achieve a low earth orbit with kerosine and liquid oxygen! Assuming a payload of 1000 kg and an energy density of 10^7 J/kg for the fuel, the total energy would be E = (25*10^3 kg)(10^7 J/kg) =~ 250 GJ!

    The wonderful thing about rockets that don't carry fuel with them is that there is no exponential dependency on initial mass. The energy required is simply the orbital energy, given by half the gravitational potential energy (derivation mercifully omitted) of the payload, given by E = -(G m0 M)/2r. The energy in this case, omitting concerns of efficiency, would be

    E = (6.67*10^-11 Nm^2/kg^2)(5.98*10^24 kg)(1000 kg)/(2*6400 km) =~ 30 GJ

    The savings in energy is almost a factor of ten!

    Michael. [michael-forman.com]

    P.S. - Lots of derivations late at night. Be merciful in the event of errors.
    • The energy required is simply the orbital energy, given by half the gravitational potential energy (derivation mercifully omitted) of the payload, given by E = -(G m0 M)/2r.

      That's not actually true at all. For a few reasons:

      a) some (a lot) of the energy ends up in moving the exhaust around (for example you have to throw it downwards to get thrust from it- unlike the case where you carry the fuel with you the propellent has to end up moving downwards, since it was stationary when you met it).

      b) gravity


      • Good points.

        However, the original post is a first-order approximation of the required energy. It is meant to highlight that one system's required fuel weight is exponential while the other's is not. Let's not let excessive details (which apply similarly to both vehicles) obfuscate the elegant simplicity of the rocket equation.

        Your statement that a reduction in fuel by a factor of ten is not possible is very wrong. For a given orbit, provided exhaust velocities are equal, a rocket which does not car
        • If you're vaporizing things, you have great flexibility in your choice of fuels. I wonder how vaporized Uranium would compare to heated air?
          • Apart from being radioactive, it's a heap of junk ;-) (Sorry!)

            The problem is that because it is such a heavy atom when you heat it, it ends up moving very slowly. By conservation of momentum, your rocket ends up moving much more slowly than if you had used hydrogen, or even nitrogen for the same mass of fuel (the fuel would be much denser, but still, it turns out to be a big, big loss).

        • Your statement that a reduction in fuel by a factor of ten is not possible is very wrong.

          What statement? I said your calculation that you would only need 10% of the energy was bogus; and I stand by that. In externally powered airbreathing rockets as we are discussing here, the energy and the fuel are unrelated; or are only related by the trajectory you've chosen to use.

          For a given orbit, provided exhaust velocities are equal, a rocket which does not carry its fuel will always use less fuel.

          Trivially tr

        • I knew this was a large subject, when I started it, but wanted present the concept of the exponential rocket equation. I'm working on a full write up on my site and should have something up by the next slashback.

          I don't think I'm going to hold my breath on this. You don't appear to know the difference between energy and fuel, and waving your hand like:

          Let's not let excessive details (which apply similarly to both vehicles) obfuscate the elegant simplicity of the rocket equation.

          Really doesn't cut it w


          • Sir, it's bad form for a scientist to tell people that they don't know what they're talking about. If I am incorrect, exercise the option of teaching rather than insulting.

            Anyway, since I don't want you holding (or refusing to hold your breath), I did a little research. For those, who are still interested, below is a wonderful set of links to websites that discuss the rocket equation. The second is my favorite. Enjoy!

            Teachin' Science [mit.edu]
            Rocket Equation Applet [spacetethers.com]
            Wolfram [asi.org]

            Michael. [michael-forman.com]
  • microwave (Score:2, Interesting)

    by savuporo ( 658486 )
    Microwaves (~100GHZ range ) get through the air almost without energy loss, thats what makes Solar Power Satellites concept feasible at all. I dont remember which, but one Japanese semiconductor corp is planning to put up small sats to beam power to handheld devices via microwave.
    • I dont remember which, but one Japanese semiconductor corp is planning to put up small sats to beam power to handheld devices via microwave.

      that sounds dangerous. i don't want the same microwaves that cook my food(or even waves in the same spectrum) being beamed from over head just so i don't have to replace the batteries in my pda. it is stuff like this that makes me trust technology less and less.

      i know that was off topic, but it is my two cents.

      on topic, perhaps they could use a swarm of these(say
  • http://www.space.com/businesstechnology/technolog y /laser_propulsion_000705.html

    I remember reading about this several years ago in a magazine. This is just one of the many articles ou there on the subject. I know they have sent the object up a couple hundred feet untethered.

    There was also another article that used microwave power to gernerate a sort of force field around the nose of a space craft to remove drag and possible the shockwave. (Somethig spike was the name). Just some cool technologies that
  • The big problem with microwaves is focusing them down. For this to work you need most of the microwave energy you are pointing at the vehicle to make it to the vehicle.

    Normally when microwaves are used for sending signals, for example satellite TV or point-point transmission, most of the power ends up missing the receiver, but the receiver amplifies the signal using power from the mains.

    When you have a rocket, there's obviously no power cord ;-), so you need the vehicle to catch as much of the microwaves

    • What about Left-Handed Materials?http://www.aip.org/enews/physnews/2000/ s plit/pnu476-1.htm Perhaps they would be capable of focusing the beam a little tighter? ... and once the "Rocket" is high enough, why not use more than one transmitter... have the transmitters arranged in consecutive circles. As long as the rocket is high enough then there will be more vectors for the microwaves to approach. For that matter maybe they could setup a microwave interferometer, have multiple larger frequencies converge in
      • What about Left-Handed Materials?

        Nah. Doesn't work. You have to be approximately 1 wavelength away for that to work, in this case we would be millions of wavelengths.

        and once the "Rocket" is high enough, why not use more than one transmitter... have the transmitters arranged in consecutive circles.

        Provided the rings are within a wavelength of each other; yup. Otherwise, nope; you get a horrible diffraction grating effect and most of the power slops around and probably takes out bystanders.

  • Microwaves work on principle of heating up water molecules in food. I'd imagine it works on similar principle in expanding the air mostly by exciting the water molecules within it. If so, I would think that water molecules are much more abundant at sea level then a few miles up, and non existant past the troposphere. Making microwave not practical for any long distance lifting. I'd imagine it'd be more practical to build a launch pad on top of a fairly high mountain and fire rockets from there.
  • hey- wouldn't it be cool if they built a network of microwave cannons and juggled passengers in rockets all over the world?
  • Not long ago I remember reading about a "directed energy weapon" intended for military use in non-lethal "crowd control." This crowd control device is actually a very short wavelength, high power microwave beam radiated from an antenna on the roof of a vehicle. It is supposed to produce a buring pain in the skin of those in the beam, but is supposed to be a non-lethal because, while it feels like a burn (and perhaps the microwave beam could cause REAL burns) the pain induced supposedly can be stopped sim

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