Will Spacecraft ever Go Faster than the speed of Light?

Various - See Text ^ | 16 FEB 2003 | Various

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Will Spacecraft ever Go Faster than the speed of Light?
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Source list and references included.
Primary Sources include MSNBC,NASA,Analog, and other online publications.
February 16 2003

 Marc Millis, who manages NASA?s Breakthrough Propulsion Physics Program, says he?s more interested in ways ?to propel spacecraft farther, faster, more efficiently? than in the grand cosmological questions. ?And my ears perk up more when I hear about new experimental evidence than theories,? he says. There are a number of such theories based on experimental evidence. His top three of interest are:

1. Photon Tunneling.
   Some experiments have indicated that photons can appear to tunnel through barriers at speeds faster than light, but researchers are still sorting out the quantum physics behind such phenomena.
   

2. Neutrino Rest Mass.
   Some experiments have come up with an imaginary number for the rest mass of neutrinos ? a result so baffling that most physicists say the data must be in error. ?If indeed those data are correct, then imaginary mass is a signature characteristic of a tachyon, a faster-than-light particle,? Millis says.
   
3. Vacuum Fluctuations.
   Quantum physics dictates that even the vacuum of space contains some energy. In fact, some physicists have said a coffee cup full of empty space contains enough energy to boil away Earth?s oceans. But can that energy be extracted or used to propel spaceships? Millis says the outlook is uncertain: ?Very obviously there?s no free lunch in this scheme, but it does provide new clues from which to search for propulsion breakthroughs.?
   

Faster-than-light speeds in tunneling experiments: an annotated bibliography

Revision and enlargement of this page are in progress, although currently stalled. I've given up setting concrete dates - a more thorough text is in the process of being written and, say, 70% done (January 2001), and until a more complete overhaul, I'll add some more references in a piecemeal fashion, below.

One central tenet of special relativity theory is that light speed is the greatest speed at which energy, information, signals etc. can be transmitted. In many physics-related internet newsgroups, claims have appeared that recent tunneling experiments show this assumption to be wrong, and that information can indeed be transmitted by speeds faster than that of light - the most prominent example of "information" being a Mozart symphony, having been transmitted with 4.7 times the speed of light. In this document, I've tried to collect the major references on these faster-than-light (FTL)-experiments. If I find the time, I will develop this into a written introduction on the topic of FTL speeds and tunneling, so far it is merely a (possibly incomplete) collection of references. If anyone has relevant additions/comments, I'd appreciate a mail.

Most of the references are to the technical literature, presuming that the reader has at least a basic grasp of physics. However, as usual, those articles have abstracts and conclusions, which give an overview of what the article is about. Some references that are in German are omitted here, but can be found in the german version of this page.

What's this all about, anyway?

In recent years, some physicists have conducted experiments in which faster-than-light (FTL) speeds were measured. On the other hand, Einstein's theory of special relativity gives light speed as the absolute speed limit for matter and information! If information is transmitted faster, then a host of strange effects can be produced, e.g. for some observers it looks like the information was received even before it was sent (how this comes about should be described in elementary literature on special relativity). This violation of causality is very worrysome, and thus special relativity's demand that neither matter nor information should move faster than light is a pretty fundamental one, not at all comparable to the objections some physicists had about faster-than-sound travel in the first half of this century.

So, has special relativity been disproved, now that FTL speeds have been measured? The first problem with this naive conclusion is that, while in special relativity neither information nor energy are allowed to be transmitted faster than light, but that certain velocities in connection with the phenomena of wave transmission may well excede light speed. For instance, the phase velocity of a wave or the group velocity of a wave packet are not in principle restricted below light speed. The speed connected with wave phenomena that, according to special relativity, must never exceed light speed, is the front velocity of the wave or wave packet, which roughly can be seen as the speed of the first little stirring that tells an observer "Hey, there's a wave coming". Detailled examinations of the differences between the velocities useful to describe waves can be found in the classic book

• Brillouin, L. 1960 Wave Propagation and Group Velocity. NY: Academic Press.

Basic information on quantum tunneling can be found in the introductory quantum theory literature.

Characteristic of the discussion of the FTL/tunneling experiments is that the experimental results are relatively uncontroversial - it is their interpretation that the debate is about. As far as I can see, right now there is a consensus that in neither of the experiments, FTL-front velocities have been measured, and that thus there is no contradiction to Einstein causality or to special relativity's claim that no front speed can exceed light speed. The discussion how much time a particle needs to tunnel through a barrier has been going on since the thirties and still goes on today, as far as I can tell. This discussion is about "real" tunneling experiments, like the ones a Berkeley group around Raymond Chiao has done, as well as experiments with microwaves in waveguides (that do not involve quantum mechanics) like those of Günter Nimtz et al. An overview of the discussion (including lots of further references) can be found in

• Hauge, E.H. & Støvneng 1989, Review of Modern Physics 61, S. 917--936.

The Berkeley group gives a general overview of their research at

• http://www.physics.berkeley.edu/research/chiao/research.html

An experiment of theirs, where a single photon tunnelled through a barrier and its tunneling speed (not a signal speed!) was 1.7 times light speed, is described in

• Steinberg, A.M., Kwiat, P.G. & R.Y. Chiao 1993: "Measurement of the Single-Photon Tunneling Time" in Physical Review Letter 71, S. 708--711

Articles concerned with the propagation of wave packets that happens FTL and is somewhat complicated by the fact that the waves "borrow" some energy from the medium, but does not violate causality, are

• Chiao, R.Y. 1993: "Superluminal (but causal) propagation of wavepackets in transparent media with inverted atomic populations" in Phys. Rev. A 48, B34.

• Chiao, R.Y. 1996: "Tachyon-like excitations in inverted two-level media" in Phys. Rev. Lett. 77, 1254.

Aephraim Steinberg, who is a former graduate student of Chiao's, has written two papers especially on the problem of tunneling time, which are available online at

• Aephraim M. Steinberg 1995: "Conditional probabilities in quantum theory, and the tunneling time controversy" in Phys. Rev A52, 32-42 (was preprint quant-ph/9502003).

• Aephraim M. Steinberg 1995: "How much time does a tunneling particle spend in the barrier region? " in Phys. Rev. Lett. 74, 2405-9 (was preprint quant-ph/9501015).

Some other papers of Chiao's Berkeley group are also online, e.g.

• Aephraim M. Steinberg, Raymond Y. Chiao 1995: "Sub-femtosecond determination of transmission delay times for a dielectric mirror (photonic band gap) as a function of angle of incidence" in Phys. Rev. A51, 3525/8 (was Preprint quant-ph/9501013).

• Raymond Y. Chiao, Paul G. Kwiat, Aephraim M. Steinberg: " Quantum non-locality in Two-Photon Experiments at Berkeley" (International Workshop on Laser and Quantum Optics, Nathiagali, Pakistan, 9-14 July 1994) in Quantum and Semiclassical Optics 7, 259-78 (was preprint quant-ph/950101).

Earlier experiments by Günter Nimtz of Cologne University (Universität Kön), with whose experiments most of the later newspaper articles are concerned, have been published as

• Enders, A. und G. Nimtz 1993, "Evanescent-mode propagation and quantum tunneling" in Phys. Rev. E 48, S. 632-634.

• Enders, A. und G. Nimtz 1993, J. Phys. I (France) 3, S. 1089

• Nimtz, G. et al. 1994: "Photonic Tunneling Times"in J. Phys. I (France) 4, 565.

A description of the equivalence between these microwave-experiments and quantum mechanical tunneling is described in

• Martin, Th. und Landauer, R. 1991: "Time delay of evanescent electromagnetic waves and the analogy to particle tunneling" in Phys. Rev. A 45 , S. 2611-2617.

In reaction to Nimtz' publications, a number of articles appeared which deal with a) why causality is not violated in these experiments, and b) how the results of the experiments come about. These are

• Deutch, J.M. und F.E. Low 1993: "Barrier Penetration and Superluminal Velocity" in Ann. Phys. (NY) 228, S. 184-202.

• Hass, K. und P. Busch 1994: "Causality of superluminal barrier traversal" in Phys. Lett. A 185, S. 9-13.

• Landauer, R. und Th. Martin 1994: "Barrier interaction time in tunneling" in Rev. Mod. Phys. 66, S. 217-228.

• Azbel, M. Y. 1994: "Superluminal Velocity, Tunneling Traversal Time and Causality" in Solid State Comm. 91, S. 439-441.

Nimtz's reply and general observations on causality and his experiments can be found in

• Heitmann, W. und G. Nimtz 1994: "On causality proofs of superluminal barrier traversal of frequency band limited wave packets" in Phys. Lett. A 196, S. 154-158.

As far as the more recent experiments of Nimtz are concerned, especially the popular tunneling of parts of Mozart's 40th symphony with 4.7fold light speed, I have not been able to find references to a technical article yet. Heitman/Nimtz 1994 (see above) refer to it as "H. Aichmann and G. Nimtz, to be published", I haven't found it in Physics Abstracts (up to July 1996, I think I should look again soon), though.

the problem of tunneling times is also the topic of some articles I've found in the quantum physics (quant-ph) archive, namely

• Toralf Gruner, Dirk-Gunnar Welsch: Photon tunneling through absorbing dielectric barriers, Preprint quant-ph/9606008

• Andrea Begliuomini, Luciano Bracci: The tunneling time for a wave packet as measured with a physical clock Preprint quant-ph/9605045

• M. S. Marinov, Bilha Segev On the concept of the tunneling time Preprint quant-ph/9603018

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Supplements: (May 5, 1999 and Jan 29, 2001)

• Aichmann, H., G. Nimtz and H. Spieker: "Photonische Tunnelzeiten: sunb-- und superluminales Tunneln" in Verhandlungen der Deutschen Physikalischen Gesellschaft 7, 1995, S. 1258.
  I'm listing this brief publication (a conference abstract) despite its being in German as it is the only publication directly referring to the tunneling of the Mozart symphony that I know of. The following article has much more content:

• Nimtz, G. and W. Heitmann: "Superluminal Photonic Tunneling and Quantum Electronics" in Progress in Quantum Electronics 21(2) (1997), S. 81-108.
  Contains an expose of Nimtz' interpretation of his and other tunneling experiments.

• Chiao, R.Y. Chiao and A.M. Steinberg: "Tunneling Times and Superluminality" in Progress in Optics XXXVII (1997), S. 345-405.
  Good summary of the "conventional" view why there is no faster-than-light information transfer in these tunneling experiments.

• Mitchell, M.W. and R.Y. Chiao: "Causality and negative group delays in a simple bandpass amplifier" in American Journal of Physics 66(1) (1998), S. 14-19.
  Describes a very simple setup with the help of which one can understand how faster-than-light (or even negative) group and "signal"-velocities can occur without any violation of causality and without any faster-than-light information transfer.

• Diener, G.: "Superluminal group velocities and information transfer" in Physics Letters A223 (1996), S. 327-331.
  General article about the pulse reshaping which, in the conventional interpretation, explains the faster-than-light (or negative) group velocities.

The following references are from the proceedings of the workshop "Superluminal(?) Velocities: Tunneling time, barrier penetration, non-trivial vacua, philosophy of physics", organized by F. W. Hehl, P. Mittelstaedt and G. Nimtz, which took place in Cologne, June 6-10, 1998.

I. Evanescent mode propagation and simulations

• A.M. Steinberg et al.: "An atom optics experiment to investigate faster-than-light tunneling" in Annalen der Physik (Leipzig), 7 (1998), S. 593-601.

• M. Büttiker and H. Thomas: "Front propagation in evanescent media" in Annalen der Physik (Leipzig), 7 (1998), S. 602-617.

• G. Nimtz: "Superluminal signal velocity" in Annalen der Physik (Leipzig), 7 (1998), S. 618-624.

• A. A. Stahlhofen and H. Druxes: "Observable tachyons in the tunneling regime?" in Annalen der Physik (Leipzig), 7 (1998), S. 625-630.

• X. Chen and C. Xiong: "Electromagnetic simulation of the evanescent mode" in Annalen der Physik (Leipzig), 7 (1998), S. 631-638.

• G. Diener: "Energy balance and energy transport velocity in dispersive media" in Annalen der Physik (Leipzig), 7 (1998), S. 639-644.

• H. D. Dahmen et al.: "Quantile motion of electromagnetic waves in wave guides of varying cross section and dispersive media" in Annalen der Physik (Leipzig), 7 (1998), S. 645-653.

• E. Capelas de Oliveira and W. A. Rodrigues Jr.:"Superluminal electromagnetic waves in free space" in Annalen der Physik (Leipzig), 7 (1998), S. 654-659.

II. Superluminal quantum phenomena

• F. E. Low: "Comments on apparent superluminal propagation" in Annalen der Physik (Leipzig), 7 (1998), S. 660-661.

• C. R. Leavens and R. Sala Mayato: "Are predicted superluminal tunneling times an artifact of using the nonrelativistic Schrödinger equation?" in Annalen der Physik (Leipzig), 7 (1998), S. 662-670.

• J. G. Muga and J. P. Palao: "Negative time delays in one dimensional absorptive collisions" in Annalen der Physik (Leipzig), 7 (1998), S. 671-678.

• S. Brouard and J. G. Muga: "Transient increase of high momenta in quantum wave-packet collisions" in Annalen der Physik (Leipzig), 7 (1998), S. 679-686.

• C. Bracher and M. Kleber: "Minimum tunneling time in quantum motion" in Annalen der Physik (Leipzig), 7 (1998), S. 687-694.

• D. Kreimer: "Locality, QED and classical electrodynamics" in Annalen der Physik (Leipzig), 7 (1998), S. 695-699.

• K. Scharnhorst: "The velocities of light in modified QED vacua" in Annalen der Physik (Leipzig), 7 (1998), S. 700-709.

• P. Mittelstaedt: "Can EPR-correlations be used for the transmission of superluminal signals?" in Annalen der Physik (Leipzig), 7 (1998), S. 710-715.

• G. C. Hegerfeldt: "Instantaneous spreading and Einstein causality in quantum theory" in Annalen der Physik (Leipzig), 7 (1998), S. 716-725.

• G. F. Melloy and A. J. Bracken: "The velocity of probability transport in quantum mechanics" in Annalen der Physik (Leipzig), 7 (1998), S. 726-731.

• H. M. Krenzlin et al.: "Wave packet tunneling" in Annalen der Physik (Leipzig), 7 (1998), S. 732-736.

III. Causality, superluminality and relativity

• P. Weingartner: "Causality in the natural sciences" in Annalen der Physik (Leipzig), 7 (1998), S. 737-747.

• U. Schelb: "On the role of a limiting velocity in constructive spacetime axiomatics" in Annalen der Physik (Leipzig), 7 (1998), S. 748-755.

• V. Gasparian et al.: "On the application of the Kramers-Kronig relations to the interaction time problem" in Annalen der Physik (Leipzig), 7 (1998), S. 756-763.

• E. Recami et al.: "Superluminal microwave propagation and special relativity" in Annalen der Physik (Leipzig), 7 (1998), S. 764-773.

• H. Goenner: "Einstein causality and the superluminal velocities of the Cologne microwave experiment" in Annalen der Physik (Leipzig), 7 (1998), S. 774-782.

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Neutrino Physics: Curiouser and Curiouser

by John G. Cramer

Alternate View Column AV-54
Keywords: solar neutrinos SAGE gallium homestake chlorine tritium endpoint imaginary mass
Published in the September-1992 issue of Analog Science Fiction & Fact Magazine;
This column was written and submitted 2/15/92 and is copyrighted ©1992 by John G. Cramer.
All rights reserved. No part may be reproduced in any form without
the explicit permission of the author.

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New data on the nature of neutrinos has been appearing recently which is very strange indeed. Second generation solar neutrino detectors and neutrino rest-mass measurements are both telling us that this elusive particle is even more peculiar than had been previously supposed.

Wolfgang Pauli first suggested the existence of what we now call the neutrino in order to preserve the law of conservation of energy. Previously, in 1911, James Chadwick had demonstrated that in the radioactive process called beta decay the emitted "beta particle" (now known to be an electron) was emitted with some random amount of its kinetic energy missing. Instead of the expected sharp spike of well-defined kinetic energy, a sample of many such emitted electrons showed that their kinetic energies were distributed over a broad bump-like distribution.

Following the discovery of the missing energy in beta decay many physicists, Niels Bohr among them, were ready to abandon the law of conservation of energy. But Pauli had a better idea: he guessed that the missing energy was being removed by a new particle that was invisible to Chadwick's detectors. We now know that he was correct.

Like the electron the neutrino spins on its axis like a tiny top, but unlike the electron it has no electric charge, little or no mass, it interacts only very weakly with matter, and it always travels at or near the speed of light. A neutrino can pass through light-years of lead without absorption or scattering.

We now know that neutrinos come in several distinct varieties or "flavors". For each of the three charged lepton flavors, electron (e), mu lepton (µ) and tau lepton ( ), there is corresponding neutrino flavor: the electron neutrino ( _e), mu neutrino ( _µ), and tau neutrino ( ), and each flavor comes in matter and antimatter varieties.

Neutrinos also play an important role in astrophysics. In stars the fusion reactions are fueled by a medium that is essentially all protons. During the fusion process about half of the proton participants are converted into neutrons through weak interaction processes that involve neutrinos. A proton in some nucleus is transformed to a neutron, and at the same time a positron (anti-matter electron) and a neutrino are emitted and share the available energy. The neutrinos produced in such fusion reactions exit the star at the speed of light, carrying their share of the energy away with them.

The result is that all stars are bright sources of energetic neutrinos. About 610 trillion neutrinos produced about 8.3 minutes ago in fusion reactions at the center of our sun are passing through your body in the second it takes to read this line. If it is night outside as you read this, the solar neutrinos are passing through the earth to reach you. There are so many neutrinos streaming in our direction from the sun that it is possible to detect them, even though the chances of detecting any particular neutrino are extremely small.

The first successful experiment to detect neutrinos from the sun was mounted in 1968 in the Homestake gold mine in Lead, South Dakota by Ray Davis and his group from Brookhaven National Laboratory. This experiment, conducted 850 feet below ground level in a 100,000 gallon tank filled with per-chloro-ethylene cleaning solvent, has been in continuous operation for well over two decades and has produced a famous result. Only about 1/3 of the expected number of solar neutrinos are detected. Either the sun is producing only 1/3 of the neutrinos that it should, or else the Homestake detector is somehow missing 2/3 of them. This neutrino deficiency was later confirmed by the Kamiokande II detector in Japan which, although it operates on a different principle, is sensitive to neutrinos in about the same energy range as the Homestake detector.

This puzzling deficiency of solar neutrinos, usually referred to as "the solar neutrino problem", has prompted a second generation of solar neutrino experiments. The first second generation experiment to produce results is SAGE, an acronym for the "Soviet-American Gallium Experiment". The experiment was initiated as a joint venture, with the Soviet scientists providing the deep underground site and about $25 million worth of gallium, while the Americans provided the computers, detection electronics, and other hardware. The breakup of the Soviet Union has created a problem of nomenclature for the SAGE experiment, which is still in progress. The experiment is located within the territorial boundaries of Russia, and so it has been suggested that perhaps the acronym should be changed to "RAGE".

In the SAGE detection system a large quantity of gallium (element 31) is purified and held in underground tanks, waiting for solar neutrinos to transmute the gallium-71 isotope in the tanks to radioactive germanium-71, which has a half life of 11.4 days. A chemical procedure separates the few radioactive germanium atoms from the gallium and transports them to a sensitive detector where their decays are counted.

If the results of the Homestake solar neutrino experiment were puzzling, the SAGE results are shocking: in over a year of counting, the net number of solar neutrinos they have detected, after subtraction of a small background, is zero. In an operating period during which hundreds of neutrinos should have been detected, none are counted.

This null result from SAGE is very difficult to explain. The system is supposed to be detect neutrinos in a lower range of energies that are not accessible for the Homestake and Kamiokande II detectors. The strong implication of the two results is that there is not only a suppression of solar neutrinos, but that it is greater at lower energies than at high.

I will not, because of space limitations, discuss in detail theories that seek to explain these observations. The most plausible explanations use the concept of "neutrino oscillations", in which electron neutrinos are converted into mu neutrinos or tau neutrinos in flight, neutrino flavors that would be unable to transmute gallium to germanium in the SAGE detector.

Other second generation solar neutrino detectors in Italy and Canada are about to go into operation. We can expect new data from these experiments which should provide new insights on the solar neutrino problem.

An even more puzzling result seems to be coming from several recent attempts to measure the rest mass of the electron neutrino. Why do the three neutrinos species, unlike their charged lepton brothers and their quark cousins, have rest masses that are nearly (or exactly) zero? The standard model of particle physics is silent on this question. Unlike the photon, which must have zero mass because it is the mediating particle of the infinite-range electromagnetic force, there is no fundamental reason why neutrinos should be massless. They just are, as nearly as we can tell from measurement.

The best technique for measuring the neutrino rest mass does so indirectly by examining the energy spectrum of electrons produced in a low-energy nuclear beta decay. The "end-point" or region of the electron energy spectrum where the highest energy electrons are found is most sensitive to the mass of the e-neutrino (or e-anti-neutrino, which should have identical mass). If the neutrino has zero mass, the distribution near the end-point smoothly merges into the baseline. But if the neutrino has a small mass, the distribution at the end-point is chopped off early, producing a "nose" with an abrupt edge at the end of the electron energy distribution.

Measurements performed in this way have indicated that the rest mass-energy of the electron neutrino must be less than about 15 electron-volts. A number of second-generation experiments have recently been initiated to improve this limit by high-precision measurements of the end-point region of the beta decay of tritium, the mass-3 isotope of hydrogen, which because of its 18.6 keV transition energy is the lowest energy beta decay known. The very low energy of the transition enhances the "nose" effect produced by the neutrino mass at the end-point and makes for the most sensitive measurements.

It is not widely appreciated that the end-point technique does not actually measure the mass of the neutrino. Because of the way that the neutrino mass affects the electron energy spectrum, the measured quantity is the square of the neutrino mass.

And this is where the interesting, although statistically shaky, results appear: of the six most recent experimental determinations of neutrino mass, all have given negative values of the mass-squared to within the statics of the measurements. The experimental observation is that in the vicinity of the end point the yield of electrons lies above the zero-mass line, while for neutrinos with non-zero real mass, the electron yield should lie below this line. The measured mass-squared values are negative to an accuracy of several standard deviations in the most recent of these experiments.

These experimenters have been strangely quiet about mass-squared measurements with negative values. If the results had been positive by the same amount, the literature would be filled with claims that a non-zero value for the neutrino mass had been established. But a negative mass-squared is not something that can be easily publicized.

You obtain the measured mass value from a mass-squared measurement by taking the square root of the measured value. However, the square root of a negative number is an imaginary number. Thus the measurements could, in principle, be taken as an indication that the electron neutrino has an imaginary mass.

What are the physical implications of a particle with an imaginary rest mass? Gerald Feinberg of Columbia University has suggested hypothetical imaginary-mass particles which he has christened "tachyons". Tachyons are particles that always travel at velocities greater than the speed of light. Instead of speeding up when they are given more kinetic energy, they slow down so that their speed moves closer to the velocity of light from the high side as they become more energetic. Feinberg argued that since there are no physical laws forbidding the existence of tachyons, they may well exist and should be looked for. This has prompted a number of experimental searches for tachyons which, up to now, have produced no convincing evidence for their existence.

Some theoretical support for the existence of tachyons, however, has come from superstring theories. These "theories of everything" can predict the masses and other properties of fundamental particles. It has been found that some superstring theories predict a family of particles with a lowest-mass member that is "tachyonic", in that it has a negative mass-squared. I should add that such predictions normally lead to the rejection of the theory as "unphysical".

So, are neutrinos tachyons? Probably not. It is far more likely that the negative values found in the neutrino mass-squared measurements originate in some unsuspected experimental effect. Nevertheless, it is interesting to contemplate the possibility that the electron neutrino is a tachyon and to ask whether it is possible in the light of available data.

Supernova 1987A, for example, might be taken as a "test bed" for the tachyonic neutrino hypothesis because both the light and the neutrinos from the explosion had to cover 160,000 light years to travel from the Large Magellanic Cloud to our detectors on earth. We could view SN-1987A as a 160,000 year race between photons and neutrinos, with the fastest particles reaching the finish line first.

In fact, the neutrinos were observed to arrive 18 hours before the photons. However, this is attributed to stellar dynamics rather than FTL neutrinos. The neutrinos can leave the exploding star at once, while the photons must wait until the explosive shock wave travels from the core of the collapsing star to its surface. The more important fact is that there was a 12 second time spread between the arrival of the first detected neutrinos and the last and the apparent grouping of the arriving neutrinos in "clumps" (possibly the result of poor statistics). This could be (but has not yet been) used to place an upper limit on how "tachyonic" the electron neutrino could be.

And so, in summary, the neutrino mysteries continue. Is the electron neutrino a tachyon? Does it change its flavor in transit from the sun to the earth? Watch this column for future late-breaking developments in neutrino physics. The only thing that is clear at the moment is that we do not have the final word on this most peculiar and enigmatic of fundamental particles.

Warp Drive, When?

Some Emerging Possibilities

The following section has a brief description of some ideas that have been suggested over the years for interstellar travel, ideas based on the sciences that do exist today.

• Lists of Some Intriguing Emerging Physics
• Lists of some preparatory propulsion research
• General Relativity
• Vacuum Fluctuations of Quantum Physics
• 1994 Workshop on Faster-Than-Light Travel

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Lists of Some Intriguing Emerging Physics

Science and technology are continuing to evolve. In just the last few years, there have been new, intriguing developments in the scientific literature. Although it is still too soon to know whether any of these developments can lead to the desired propulsion breakthroughs, they do provide new clues that did not exist just a few short years ago. A snapshot of just some of the possibilities is listed below:

• 2001 BPP-Sponsored Papers presented at the BPP Sessions of the July 2001 Joint Propulsion Conference in Salt Lake City, Utah. (intended for technical audiences) [This link will take you out of the WDW site and into the BPP Project site.]
• 1996 Eberlein: Theory suggesting that the laboratory observed effect of sonoluminescence is extraction of virtual photons from the electromagnetic zero point fluctuations.
• 1994 Alcubierre: Theory for a faster-than-light "warp drive" consistent with general relativity.

• 1994 Haisch, Rueda, and Puthoff: Theory suggesting that inertia is a consequential effect of the vacuum electromagnetic zero point fluctuations.
• 1992 Podkletnov and Nieminen: Report of superconductor experiments with anomalous results -- evidence of a possible gravity shielding effect.
• 1989 Puthoff: Theory extending Sakharov?s 1968 work to suggest that gravity is a consequential effect of the vacuum electromagnetic zero point fluctuations.
• 1988 Herbert: Book outlining the loopholes in physics that suggest that faster-than-light travel may be possible.
• 1988 Morris and Thorne: Theory and assessments for using wormholes for faster-than-light space travel.

Lists of some preparatory propulsion research

These emerging ideas are all related in some way to the physics goals for practical interstellar travel; controlling gravitational or inertial forces, traveling faster-than-light, and taking advantage of the energy in the space vacuum. Even though the physics has not yet matured to where "space drives" or "warp drives" can be engineered, individuals throughout the aerospace community and across the globe have been tracking these and other emerging clues. Most of this work has been fueled purely from the enthusiasm, talent, and vision of these individuals, but on occasion, there has been small support from their parent organizations.

Surveys & Workshops:

• 1972 Mead Jr.: Identification and assessments of advanced propulsion concepts.
• 1982 Garrison, et al.: Assessment of ultra high performance propulsion.
• 1986 Forward: Assessment of the technological feasibility of interstellar travel.
• 1990 NASA Lewis Research Center: Symposium "Vision-21: Space Travel for the Next Millennium."
• 1990 British Aerospace Co.: Workshop to revisit theory and implications of controlling gravity.
• 1990 Cravens: Assessment of alternative theories of electromagnetics and gravity for propulsion.
• 1991 Forward: Assessment of advanced propulsion concepts.
• 1994 Bennett, et al.: NASA workshop on the theory and implications of faster-than-light travel.
• 1994 Belbruno: Conference assessing: "Practical Robotic Interstellar Flight: Are We Ready?"
• 1995 Hujsak & Hujsak: Formation of the "Interstellar Propulsion Society."

Theory:

• 1988 Forward; 1989, Winterberg: Further assessments of Bondi?s 1957 theory regarding hypothetical negative mass and its propulsive implications.
• 1984, Forward: Conceptual design for a "vacuum fluctuation battery" to extract energy from electromagnetic fluctuations of the vacuum based on the Casimir effect (predicted 1948, measured 1958 by Sparnaay).
• 1994; Cramer, et. al.: Identification of the characteristics of natural wormholes with negative mass entrances that could be detectable using existing astronomical observations.
• 1996; Millis: Identification of the remaining physics developments required to enable "space drives," including the presentation and assessment of seven different hypothetical "space drive" concepts.

Experiments:

• 1991; Talley: Tests of "Biefeld-Brown" effect (results negative).
• 1995; Millis & Williamson: Tests of Hooper?s gravity - electromagnetic coupling claim (results negative).
• 1995; Schlicher: Evidence for thrusting using "Unsymmetrical Magnetic Induction Fields" (unconfirmed).
• 1996; Forward: Experimental proposals for testing vacuum fluctuation theories and other mass-modification theories.

General Relativity

This is a snap shot of how gravity and electromagnetism are known to be linked. In the formalism of general relativity this coupling is described in terms of how mass warps the spacetime against which electromagnetism is measured. In simple terms this has the consequence that gravity appears to bend light, red-shift light (the stretching squiggles), and slow time. These observations and the general relativistic formalism that describes them are experimentally supported.

Although gravity?s effects on electromagnetism and spacetime have been observed, the reverse possibility, of using electromagnetism to affect gravity, inertia, or spacetime is unknown.

"Grand Unification Theories"

[graphic]

The mainstream approach to better understand this connection is through energetic particle smashing. Physicists noticed that when they collided subatomic particles together they figured out how the "weak force" and electromagnetism were really linked. They cranked up the collision energy and learned of that this new "Electro-Weak" theory could be linked to the "strong nuclear force". SO.... just crank up the power some more, and maybe we?d understand gravity too. Unfortunately, the collision energies needed are not technologically feasible, even with the Super Conductor Super Collider that got canceled, but its still a thought.

Vacuum Fluctuations of Quantum Physics

"Zero Point Energy"

Zero Point Energy (ZPE), or vacuum fluctuation energy are terms used to describe the random electromagnetic oscillations that are left in a vacuum after all other energy has been removed. If you remove all the energy from a space, take out all the matter, all the heat, all the light... everything -- you will find that there is still some energy left. One way to explain this is from the uncertainty principle from quantum physics that implies that it is impossible to have an absolutely zero energy condition.

For light waves in space, the same condition holds. For every possible color of light, that includes the ones we can?t see, there is a non-zero amount of that light. Add up the energy for all those different frequencies of light and the amount of energy in a given space is enormous, even mind boggling, ranging from 10^36 to 10^70 Joules/m3.

In simplistic terms it has been said that there is enough energy in the volume the size of a coffee cup to boil away Earth?s oceans. - that?s one strong cup of coffee! For a while a lot of physics thought that concept was too hard to swallow. This vacuum energy is more widely accepted today.

What evidence shows that it exists?

First predicted in 1948, the vacuum energy has been linked to a number of experimental observations. Examples include the Casimir effect, Van der Waal forces, the Lamb-Retherford Shift, explanations of the Planck blackbody radiation spectrum, the stability of the ground state of the hydrogen atom from radiative collapse, and the effect of cavities to inhibit or enhance the spontaneous emission from excited atoms.

The Casimir Effect:

The most straight-forward evidence for vacuum energy is the Casimir effect. Get two metal plates close enough together and this vacuum energy will push them together. This is because the plates block out the light waves that are too big to fit between the plates. Eventually you have more waves bouncing on the outside than from the inside, the plates will get pushed together from this difference in light pressure. This effect has been experimentally demonstrated.

Can we tap into this energy?

It is doubtful that this can be tapped, and if it could be tapped, it is unknown what the secondary consequences would be. Remember that this is our lowest energy point. To get energy out, you presumably need to be at a lower energy state. Theoretical methods have been suggested to take advantage of the Casimir effect to extract energy (let the plates collapse and do work in the process) since the region inside the Casimir cavity can be interpreted as being at a lower energy state. Such concepts are only at the point of theoretical exercises at this point.

With such large amount of energy, why is it so hard to notice?

Imagine, for example, if you lived on a large plateau, so large that you didn?t know you were 1000 ft up. From your point of view, your ground is at zero height. As long as your not near the edge of your 1000 ft plateau, you won?t fall off, and you will never know that your zero is really 1000. It?s kind of the same way with this vacuum energy. It is essentially our zero reference point.

What about propulsion implications?

The vacuum fluctuations have also been theorized by Haisch, Rueda, and Puthoff to cause gravity and inertia. Those particular gravity theories are still up for debate. Even if the theories are correct, in their present form they do not provide a means to use electromagnetic means to induce propulsive forces. It has also been suggested by Millis that any asymmetric interactions with the vacuum energy might provide a propulsion effect.

1994 Workshop on Faster-Than-Light Travel

In May 1994, Gary Bennett of NASA Headquarters (now retired), convened a workshop to examine the emerging physics and issues associated with faster-than-light travel. The workshop, euphemistically titled "Advanced Quantum/Relativity Theory Propulsion Workshop," was held at NASA?s Jet Propulsion Lab. Using the "Horizon Mission Methodology" from John Anderson of NASA Headquarters to kick off the discussions, the workshop examined theories of wormholes, tachyons, the Casimir effect, quantum paradoxes, and the physics of additional space dimensions. The participants concluded that there are enough unexplored paths to suggest future research even though faster-than-light travel is beyond our current sciences. Some of these paths include searching for astronomical evidence of wormholes and wormholes with negative mass entrances (searches now underway), experimentally determining if the speed of light is higher inside a Casimir cavity, and determining if recent data indicating that the neutrino has imaginary mass can be credibly interpreted as evidence for tachyon-like properties, where tachyons are hypothesized faster-than-light particles.

[Diddley]

--- taking 50 years for the round trip ---

[TigersEye]

bttt for later read.

[PatrickHenry]

Placemarker.

[BaBaStooey]

Zephram Cochrane, the John Wayne of space, invents warp drive in the 2060s right after WWIII kills half a billion people (Star Trek: First Contact). Gosh, I thought everyone knew that.

All we need is some antimatter injectors and a warp coil. Someone? Anyone?

[vannrox]

The basic ideas here will be presented both at American Physical Society March Meeting in Austin and April Meeting in Philadelphia. A Sarfatti Commentary on Decoding The Cipher of Genesis "My Father's House has many mansions." Rabbi Yeshua On Monday, February 17, 2003, at 09:31 AM, al ... wrote: > Saul Paul said: "this quantity 137.0360 can be regarded as the > hypotenuse of a right angle triangle, with the base 137 and the > height pi = 3.14159." > > Jack noted: Of course in modern cosmology post inflation and post >> 1983 as summarized in Max Tegmark's latest paper for the Wheeler >> volume, these constants are not fundamental but are contingent > > My question: Even if these constants are contingent, I wonder whether > the same right triangular relationship between the contingent > constants would be conserved, albeit at some higher or lower value? I don't know. You should read John Barrow's "Constants of Nature" ASAP - lot's of interesting tidbits on this sort of thing, e.g. Fig 4.5. The main really new idea coming out of the latest WMAP data is the almost certain reality of Level I parallel Hubble sphere universes outside each others causal range on a single spatially smooth non-fractal simply-connected (on large scale) flat infinite Level II post-inflation bubble in a chaotic cosmology. Whether this or that Hubble sphere expands, contracts, stays static balanced, accelerates or decelerates is all random. We cannot exist in most of them! This means, as first suggested seriously by Lee Smolin, I think in a limited model, the prevalence of a kind of Darwinian natural selection AKA "Weak Anthropic Principle" or WAP, in the infinity of Ezekial's "Worlds Within Worlds". Strange synchronicities like the Eddington number pattern and the delicate balance of the "fundamental" constants of nature are really evidence for the empirical reality of other parallel worlds with parallel selves. This is Tegmark's main thesis. It may even have been anticipated by Nietzsche? These almost spooky coincidences are needed in order for our form of life to exist inside a single Hubble sphere universe. The proper relation of "brane worlds" to Level I and Level II structure is left unexplained in Tegmark's paper for the Wheeler Symposium sponsored by that Religious Group of Christian Apologists - Templeton Foundation. David Deutsch's Level III "multiverse", which adds "no new story line content" to Level I parallel universes as Tegmark points out, may be based on a colossal philosophical category error of over-extrapolating UNITARY MICRO-quantum physics to the large scale MACRO-quantum vacuum structure of Super Cosmos. UNITARY MICRO-quantum physics is John A. Wheeler's IT FROM BIT This is a one-way relation with a fragile Bohm BIT quantum potential for IT particles (or BIT super potential for IT field theory) with Tony Valentini's "sub-quantal heat death" entailing "signal locality" within nonlocally entangled complex micro-systems consistent with chaotic "environmental decoherence", hence, for example "no cloning a quantum" in a MICRO-quantum computer or cryptographic or teleportation device on a seemingly "secure" C^3 channel. There is no compensating BIT FROM IT "direct back-action" for entangled micro-quantum systems, and, more importantly, for "particle beams" in controlled lab scattering experiments. Each particle beam is a realization of a UNITARY Born probability P = ||^2 ensemble with "sub-quantal heat death". The several particles in the beam are NOT mutually entangled in a good scattering experiment. In this micro-quantum case formal unitarity can be associated with conservation of statistical probability - but this property does not survive in the formation of a "superfluid" macro-quantum ground state condensate except for the residual micro-quantum "normal fluid" Heisenberg uncertainty fluctuations into and out of the macro-condensate. It is these "normal fluid" fluctuations that maintain the "generalized phase rigidity" of the macro-condensate. In the special case of the relative "zero entropy" virtual off mass shell macro-quantum vacuum condensate (0|e+(p)e-(p)|0) this PW Anderson "phase rigidity" is Sakharov's "metric elasticity" of Einstein's 1915 zero torsion geometrodynamics as a collective emergent modulated Goldstone phase mode at the Diff(4) second rank tensor level out of the micro-quantum Dirac substratum of spin 1/2 - spin 1 representations of the globally flat Poincare group P. P = T X L The "More Is Different" vacuum phase transition locally gauges at least T (4-parameter translation subgroup generated by total 4-momentum) to zero torsion Diff(4) with compensating local c-number fields and /\. It is the /\ field that pumps chaotic inflation forming the Worlds Within Worlds of Tegmark's Levels I and II. The reality of the latter two levels is shown by the new NASA WMAP evidence. Locally gauging the six-parameter Lorentz group L of the tangent fiber seems to give a compensating field Diff(4) base space homogeneous third rank tensor local "torsion field" (Kibble & Gennady Shipov) whose Diff(4) <-> L tetrad transform seems to be Jim Corum's inhomogeneous anholonomic connection field for rotating mobile Cartan frames whose centers of mass are confined to timelike geodesics of the Diff(4) group of the base space of the Level II post-inflationary bubble's "tangent bundle"? Thus, I have shown, I suspect in a Sleep Walking way, how the large scale structure of Super Cosmos (i.e. chaotic inflation of Levels I and II + M theory brane worlds "UFO universes next door") is a "More is different" Sakharov-Anderson emergence of smooth c-number fields and /\ out of the virtual BCS-BEC condensate in the globally flat micro-quantum spin 1 -spin 1/2 unstable vacuum to the more stable lower relative entropy spin 1/2 PV macro-quantum post-inflationary vacuum with LOCAL coherent order parameter (0|e+(p)e-(p)|0) at space-time point event p on a scale >> string length. This local complex numbered "spin 0" Diff(4) scalar Master Field (0|e+(p)e-(p)|0) can be written as the spin 1 gauge force invariant (0|e+(p)e-(p)|0) = |(0|e+(p)e-(p)|0)|e^i[arg(0|e+(p)e-(p)|0) - IntegralTaAu(p)^adx^u] where |(0|e+(p)e-(p)|0)| = Higgs Modulus Field and arg(0|e+(p)e-(p)|0) - IntegralTaAu(p)^adx^u = Spin 1 Gauge Force-Invariant Goldstone Phase Field = Minkowski + (1/2)Lplanck*^2{Du,Dv}[arg(0|e+(p)e-(p)|0) - IntegralTaAu(p)^adx^u] Du = ,u + TaAu(p)^a { , } is anti-commutator Lplanck*^2 = hG*/c^3 = Beckenstein BIT of Susskind "world hologram" ~ Vol^2/3/Lp*^2 NOT Vol/Lp*^3 Lplanck* >> Lplanck may be true on micro-scales. EEP eu^a(p) tetrad is from a non-spin 1 phase transform {Du,Dv}[arg(0|e+(p)e-(p)|0) - IntegralTaAu(p)^adx^u + Chi(p)] = 0 *The Diff(4) LOCAL NONLINEAR BIT FROM IT MACRO-QUANTUM Landau-Ginzburg equation that REPLACES the nonlocal linear micro-quantum Schrodinger equation HPsi = (h/i)Psi,t in configuration space is {[^;u + TaAu(p)^a][;u + TbAu(p)^b] + m(vac)^2 + b(vac)|(0|e+(p)e-(p)|0)|^2} 0|e+(p)e-(p)|0) = 0 where ;u is the Diff(4) covariant derivative in the curved background metric. This is a BOOT STRAP self-organizing self-creating globally consistent loop like Escher's "Drawing Hands" shown in my book "Destiny Matrix" http://www.1stbooks.com naturally and parsimoniously explaining the locality of the macro quantum world out of the nonlocal micro-quantum world. We do not need the miracle of von Neumann's "projection postulate" or "collapse". The micro-quantum superposition principle is modified at the macro-quantum level. Suppose we can somehow make a Josephson "weak link" between the vacuum |0) and a real superconductor |g). This would modulate the quintessent dark energy/matter /\ field. /\(p) = Lplanck*^-2[1 - Lplanck*^3|(0|e+(p)e-(p)|0) + (g|e-(p)e-(p)|g)|^2] Assume = 0 which is Einstein's 1915 non-gravitating vacuum in which Ruv(vac) = 0 is the local c-number field equation from the Einstein-Hilbert Diff(4) local 4D world action density (-det)^1/2 Ru^u That is |(0|e+(p)e-(p)|0)|^2 = Lplanck*^-3 Therefore, |(0|e+(p)e-(p)|0) + (g|e-(p)e-(p)|g)|^2 --> Lplanck*^-3 + (superconductor density) + 2Lplanck*^-3/2(superconductor density)^1/2 cos[arg(0|e+e-|0) - (g|e-e-|g) + Integral TaAu^adx^u + Berry Phase] This term appears in the BIT FROM IT Landau-Ginzburg equation as the basis for "metric engineering". Note that the Lplanck*^3 terms exactly cancel out. Therefore, the metrically engineerable dark energy/matter field is /\(p) = -Lplanck*^-1[(superconductor density) + Lplanck^-3/2(superconductor density)^1/2 cos(Gauge Invariant Dynamical Beat Phase Difference + Berry Phase)] anti-gravitating dark energy requires (superconductor density) + Lplanck^-3/2(superconductor density)^1/2 cos(Gauge Invariant Dynamical Beat Phase Difference + Berry Phase) < 0 That is (superconductor density)^1/2 + Lplanck^-3/2 cos(Gauge Invariant Dynamical Beat Phase Difference + Berry Phase) < 0 [(superconductor density)(Lplanck*)^3]^1/2 + cos(Gauge Invariant Dynamical Beat Phase Difference + Berry Phase) < 0 I also included possible topological Berry phase effects in addition to the Bohm-Aharonov-Josephson dynamical phase effects. Indeed Giovanni Modanese's model of alleged anti-gravity effects in rotating superconducting disks would be relevant here as a test. /\ > 0 (in John Peacock's 3 GR sign conventions) is anti-gravitating exotic vacuum "dark energy". /\ < 0 is gravitating exotic vacuum "dark matter" PW Anderson's "generalized phase rigidity" in this special case is precisely Andre Sakharov's "metric elasticity" of Hagen Kleinert's precipitate the "world crystal lattice" with large-scale "spacetime stiffness" G(Newton)/c^4 = 10^-33 cm/10^19 Gev = (Super String Tension)^-1 This number, like ALL misnamed "fundamental" numbers of physical parameters for our provincial Hubble Sphere in which we are stuck like Ed Abbot's "Flatlanders", is a purely Darwinian natural selection of initial conditions effect or WAP effect selecting out an infinite sub-ensemble of Hubble spheres with our form of carbon-based conscious life, out of the seemingly non-denumerable infinity of such Hubble spheres in an equally seeemingly non-denumerable infinity of chaotic post-inflationary bubbles.

[boris]

Nice formatting.

[vannrox]

SPACE is an amazing place.

During the summer I like to go out at night and look up at the stars.



If you go to the GRIN NASA Site you can see quite a large number of great HST photos that I wasn't aware existed.

[Kevin OMalley]

I agree. After all, the metric system was devised as a result of discovering the circumference of the Earth. Why not a new metric system based upon the observed speed of light at the time?

[Drango]

My wife can spend faster than light.

[boris]

"Even if it were possible to go the speed of light, the human body couldn't practically take it...It would take around 15 years accelerating with 3G's of force (which is a LOT for a constant pressure) to reach the speed of light...another 12 years to slow down...12 to speed up and 12 more to slow down on the way back...50 year minimum journey and no way to communicate with earth?..not practical...unless we find a way to freeze people and forget about them for a hundred years." Your math is wrong (unless you are including relativistic effects; I have not done that calculation). As I pointed out above, one "G" is 1.032 light years/year/year.

--Boris

[SunkenCiv]

Light Exceeds Its Own Speed Limit, or Does It?
Published: May 30, 2000 Author: JAMES GLANZ
Posted on 05/30/2000 09:13:11 PDT by H.R. Gross
http://www.FreeRepublic.com/forum/a3933e89738c3.htm

Will the speed of light always be a barrier?
Air and Space Magaine. Vol # 1 March 1978 | March 1978
Editorial Staff w/ Melvin B. Zistein
Posted on 06/12/2005 6:00:55 PM PDT by vannrox
http://www.freerepublic.com/focus/f-news/1421630/posts

[KneelBeforeZod]

KHAAAAAAAAAAAAAAAN!!!!!!!!

[SunkenCiv]

Some two or three year old topics (including this one) related to or mentioning João Magueijo:

Faster Than the Speed of Light: E = mc2, Except When It Doesn't
NY Times | 2/09/03 | George Johnson
Posted on 02/28/2003 8:57:55 AM EST by Boot Hill
http://www.freerepublic.com/focus/f-news/853725/posts

Speed of light slowing down?
WorldNetDaily | 7/31/04 | Chris Bennett
Posted on 08/01/2004 3:25:39 PM EDT by wagglebee
http://www.freerepublic.com/focus/fr/1182979/posts

[SunkenCiv]

An oldie addition to an old topic of yours. :')

At the Speed of Light
by Tim Folger
DISCOVER Vol. 24 No. 4 (April 2003)

Webb used data collected by the world's most powerful telescope -- the Keck, perched on the summit of Mauna Kea, 13,796 feet up on the Big Island of Hawaii. He looked at light from 68 quasars -- extremely bright young galaxies -- as much as 12 billion light-years from Earth. During the light's long journey to Earth, it passed through clouds of intergalactic gas. In doing so, the light's spectra changed, depending on the chemical elements in the clouds.

The details of such spectral shifts are expressed mathematically by the so-called fine-structure constant, which consists of four components, including the speed of light. The constant should remain the same no matter where or when it's measured -- that's why it's called a constant. But Webb found otherwise. In the intergalactic clouds, the "constant" was smaller than the expected value by one part in 100,000. This means one or more elements of the fine-structure constant -- possibly the speed of light -- must have varied by the same amount. If light did travel that much faster 12 billion years ago, when it left the remotest quasars Webb studied, it would be consistent with Magueijo's theory. The difference may seem tiny, but it floored physicists around the world, including its discoverer. "I was absolutely stunned, yeah," Webb says. "I certainly didn't expect it."

...According to Magueijo's calculations, the speed of light near a cosmic string would increase dramatically: A spaceship traveling on one of these fast tracks could go well above the standard speed of light—186,282 miles per second—while still traveling at a fraction of the accelerated light-speed limit around the cosmic string. The laws of special relativity would still hold—time would slow down for the travelers. But because they would be traveling at a fraction of the cosmic string's light-speed limit, the effect would be minimized; astronauts could travel to the stars and return to Earth to find that months, not centuries, had passed.

[Proud2BeRight]

Scotty could always get those warp drive engines working just in time.

[Bender2]

Non Rocket Scientist Question: "How hot does it have to be for water to burn?"

I was wondering what would be the results of a laser producing a super-hot beam on water, which is made up of hydrogen and oxygen... Which burns rather well.

Let's say a stream of good old water (or steam) was squirted into a rocket combustion chamber and was hit by a million (or more!) degree laser beam...

Would we have a very efficent conversion of h2o to thrust?

Or what?

Any comments?