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Science

Double-Slit Experiment in Time, Not Space 535

TheMatt writes "Thomas Young's double-slit experiment is a classic experiment that helped establish the wave-like nature of light. Since then, it has been done with atoms, buckyballs, and biomolecules. It has even been seen in a single molecule, and the single electron version was voted the most beautiful experiment by Physics World readers (covered previously on Slashdot). Now, PhysicsWeb is reporting that Gerhard Paulus and coworkers have conducted the double-slit experiment using a double-slit in time, not space. The "slit" was a crafted femtosecond pulse consisting of one-and-a-half cycles--say, two maxima and one minima--passed through an argon gas. Each maxima has a probability of ionizing an argon atom and producing an electron. The electrons were accelerated to a detector which observed an interference pattern since the detector had no idea which maximum produced the electron."
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Double-Slit Experiment in Time, Not Space

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  • by grub ( 11606 ) <slashdot@grub.net> on Wednesday March 02, 2005 @06:05PM (#11828821) Homepage Journal

    Just today at lunch I was saying "Wouldn't it be cool to craft a femtosecond pulse consisting of 1.5 cycles, say 2 maxima and 1 minima, passed through argon gas? We could get electrons which could be accelerated then observe the resulting interference patterns!"

    Well, that didn't fly. The guys got pissed off and yelled "Shut up and watch the stripper!" so I sheepishly went back to my titties and beer.
    • The guys got pissed off and yelled "Shut up and watch the stripper!" so I sheepishly went back to my titties...

      Ever read a biography of Feynman?

    • by gardyloo ( 512791 ) on Wednesday March 02, 2005 @06:19PM (#11828963)
      Hm... strip club....

      Gas? Check.
      Femtosecond pulses? Not that kind of club, but Check.
      Maxima with a minimum between them? Yup.

      Dude, it was all there. What else did you need?!?
    • by ShadyG ( 197269 ) <bgraymusic@gm[ ].com ['ail' in gap]> on Wednesday March 02, 2005 @07:05PM (#11829381) Homepage
      Just today at lunch I was saying "Wouldn't it be cool to craft a femtosecond pulse consisting of 1.5 cycles, say 2 maxima and 1 minima, passed through argon gas?"

      No, you have it wrong. See, It is possible to synthesize excited bromide in an argon matrix! Yes, it's an excimer, frozen in its excited state...As soon as we apply a field, we couple to a state that is radiatively coupled to the ground state.
    • by yeuph ( 452290 ) on Wednesday March 02, 2005 @10:11PM (#11830700)
      The nobel prize winning physicist, Richard Feynman, was known to work out of a strip club. He'd scribble stacks of equations on their napkins will sitting in a corner looking at the girls. When the stripclub was tried for indecency, he was the club's star witness in proving that a valuable service was being conducted there!
  • Full Text (Score:2, Informative)

    by moofdaddy ( 570503 ) *
    New look for classic experiment

    2 March 2005

    Physicists in Europe and the US have performed a novel version of the double-slit quantum-interference experiment with single electrons. In the classic version of the experiment, electrons pass through a mask containing two parallel slits and produce a pattern of bright and dark interference fringes on a screen. Now, Gerhard Paulus of Texas A&M University and co-workers in Berlin, Munich, Sarajevo and Vienna have observed an interference pattern with el
  • Comment removed (Score:3, Interesting)

    by account_deleted ( 4530225 ) on Wednesday March 02, 2005 @06:06PM (#11828835)
    Comment removed based on user account deletion
    • Re:Hrm (Score:4, Informative)

      by exp(pi*sqrt(163)) ( 613870 ) on Wednesday March 02, 2005 @06:18PM (#11828957) Journal
      So in the usual dual slit experiment the state of a photon, say, that has passed through the slits, is a superposition of two states - having gone through one slit or having gone through another slit. What makes this interesting is that the states are described by wavefunctions and the superposition is the sum of two sets of waves. As anyone who's played with water ripples knows, when two sets of waves are added you get areas where the different waves cancel or reinforce each other giving so-called interference patterns.

      In this experiment we have an atom which has a 50% chance of being ionized at time t0 and a 50% chance of being ionized at time t1 (OK, the probablities cannot literally be those values but this is an example) so we have a superposition of two states - one corresponding to an atom ionized at one time and one ionized at another time. As the wavefunction for the atoms is essentially oscillatory it means that as the wavefunctions for these two separate states evolve they are out of phase with each other (or are sums of terms that are out of phase with each other). This means we can expect constructive or destructive interference depending on the exact value of t1-t0. This is what was observed.

    • Re:Hrm (Score:5, Informative)

      by Quantum Fizz ( 860218 ) on Wednesday March 02, 2005 @07:11PM (#11829431)
      I'll explain the 'classic' double-slit experiment so you can see how this is cool, similar yet different.

      The double-slit experiment classically involved sending light through two small slits closely separated, onto a dark screen. If light was particulate, you'd expect to see only two bright spots on the screen. But you see a whole interference pattern, with the brightest spot located between the two slits.

      This is because of diffraction, and that light acts like a wave, so you get constructive and destructive interference on the screen.

      What we didn't know until the 20th century is that light consists of photons, which are individual quanta of electromagnetic radiation. These photons interfere with each other in space as they go through the slits, to give the characteristic interference pattern on the far screen. Or, that the photons don't go through a single slit, but the photons actually go through both slits, and you don't know where the photon is until you measure it (ie, let it hit the screen).

      The current experiment effectively used a laser to create two 'slits' in time. They made two quick laser pulses (really two maxima and one minimum). The pulses have some probability of creating an electron, and by making two discrete pulses in time, there is a similar 'interference pattern' associated with observing the electron at various points in time. This means that the electron wasn't created from one laser pulse or the other, but was effectively created through both slits, the time separation of which created an interference effect.

      There's no new quantum mechanics here, but here's an attempt at a layman's explanation of what's called the propagator. In classical mechanics you have a well-defined trajectory from a set of well-defined initial conditions (ie, a ball on a spring has a well-defined position and momentum at some time, and you can exactly predict where the ball will be at future times). See this article [wikipedia.org] for example.

      Quantum mechanics extends this because there is a classical path the ball would take, but also infinitely many other 'quantum' paths that can also bring the ball from position X at time 0 to position Y at time T. Many of these are classically impossible. But Quantum Mechanics deals with a wavefunction (which describes the state of the system) which is complex. So you need to consider all these other paths too, but each path has an associated phase with it. When you maintain this phase coherence between all paths, you are basically building a similar interference pattern. So when you take the modulus squared of the wavefunction to find the probability of finding the electron, you have interference from the wavefunction going through either of the two slits in time.

      The difficulty is that you have to repeat the experiment many times to see when you measure the electron, just like w/ the classical double-slit experiment you need enough photons to give a relative intensity that can be measured.

      Here's a little math for anyone curious. The time progression of a wavefunction looks like
      |Psi(t)>=exp(-i*H*t/hbar)|Psi(0)>
      where |Psi(t)> is the wavefunction at time t, i is the square root of negative one, H is the Hamiltonian Operator, hbar is the Planck constant. See here for more information on the Hamiltonian for classical [wikipedia.org] and quantum [wikipedia.org] mechanics. In many cases it's the energy operator (expressed in terms of position and momentum), and acts on discrete energy eigenstates.

      But you can see that time translation evolves the 'phase' of the wavefunction. And if the wavefunction isn't in a single energy eigenstate but a combination of them, each individual component will have have the phase evolve at a different

  • Ah yes... (Score:5, Funny)

    by Anonymous Coward on Wednesday March 02, 2005 @06:06PM (#11828837)
    I've been trying for years to do the double-slit experiment. Alas, the wife still won't go for it.
  • Uh...What he said.

    Any phycisits out there who are bored who wouldn't mind explaining this to the rest of us?
    • Bored... (Score:5, Informative)

      by PDAllen ( 709106 ) on Wednesday March 02, 2005 @06:41PM (#11829164)
      Basically, you can look at light, or electrons, or whatever, as either a particle or a wave. Sometimes one interpretation will work better (light as a particle explains the photoelectric effect, light as a wave explains interference patterns, diffraction, etc). Current state of play is that the wave interpretation is always the best way to look at things, except when you observe the system everything collapses to particles, and when something mathematically inconvenient happens (you can explain the photoelectric effect in terms of waves, but the maths is horrible).

      Classic two slit experiment with light consists of shining laser light on a barrier with two slits; each slit produces a diffraction pattern (http://en.wikipedia.org/wiki/Diffraction), the diffraction patterns interfere to produce the classic two slit pattern, see same link. This basically works because the laser light is coherent, you can (sort of) treat all the photons coming from the laser like one photon.

      If you do this with electrons, because electrons are waves, you get the same patterns. Ditto any other particle.

      Even if you do this experiment firing only one electron at a time you will get the same two-slit interference pattern, although 'common sense' tells you the electron can only pass through one of the two slits what actually happens is it passes through both at once. If on the other hand you fit a detector over one slit to register the passage of electrons, so you can tell which slit the electron passes through, you lose the interference pattern, you get two overlapping single slit diffraction patterns, which is not the same thing.

      Roughly, if you have two slits and whenever an electron is fired at the slits you do not know which slit it went through, but the classical probability (what you'd expect if you didn't know quantum mechanics) of either slit is 0.5, then you will get a two-slit pattern.

      This is basically the same experiment, except instead of two slits in space a little distance apart there are two possible source times for the electron, separated by a small time gap. There is no way to know whether a detected electron was produced at the first or second time, so the maths works out (roughly) the same as for the two slits in space case and you would expect to see the classic two-slits pattern. But it is kind of neat that someone's actually found a way to test that idea.
  • huh?! (Score:5, Insightful)

    by Dues ( 786223 ) on Wednesday March 02, 2005 @06:09PM (#11828864)
    "Adressen på den hjemmeside, du ønsker at finde, er enten forkert, eller også eksisterer hjemmesiden ikke længere. Du kan prøve følgende:
    Tjekke om adressen er stavet rigtigt. Bemærk at det har betydning, om du bruger store eller små bogstaver!"

    that may as well have been the writeup, because i don't understand a word of it.
    • Re:huh?! (Score:3, Informative)

      by Husgaard ( 858362 )
      It is a 404 - user-friendly, but only to people who read danish.
    • Rough trans: The address of the homepage you wish to find is not here or doesn't exist any longer. You can try the following: Check if the address is spelled correctly. Notice that it has meaning if you use capital or lowercase letters!

      Or maybe it says something about a moose [force9.co.uk].
    • Re:huh?! (Score:5, Informative)

      by fermion ( 181285 ) on Wednesday March 02, 2005 @06:32PM (#11829086) Homepage Journal
      Ok, here we go. There are a few experiments that have redefined the way we think of waves of matter. These often use simple apparatus but incredible levels of deductions. First, the Michelson-Morley Experiment tested the assumption that waves had to have a medium of travel. We knew that light was a wave, and waves were energy that traveled in matter, like water waves. After the great experiment, we knew that light could and did travel in a vacuum, unlike say sound waves. Another change came when Einstein discovered that he could use light to knock electrons off of atoms in a way that looked very much like a billiard ball knocking bricks of a wall. It now seemed that the photon was a particle.

      What the double slit experiment did was allow us to show that light is both. In the experiment, one shines a pinpoint of light onto two very thin slits. The physics of waves dictate that waves will interfere in a characteristic pattern. This was later used with any matter of particles to show that the wave/particle duality, that is, all suitable small things act like waves or particles depending on the circumstances.

      The experiment depends on the fact that we have no idea which slit any particular particle passes through. This uncertainty, in a certain sense, allows particles to go through both slits, which is why a single electron will interfere with itself. If we do know which slit an particle goes through, then then interference disappears. In this way we can show that particles are a wave until, in Schrödinger terms, we collapse it into a wave. So the experiment can show the duality.

      So, to summarize, when the state of any particular particle is left uncertain, and certain other conditions are met, it will interfere as a wave. What they are doing here is introducing the uncertainty through a ultra-short pulse of light. There are two ways that the pulse could interact with the surrounding particles, but the universe does not know exactly which interaction occurred. There, the strange and headache producing phenomenon of the sub atomic world are allowed to manifest. I am not sure how this is time instead of space, but it is neat.

      • Re:huh?! (Score:4, Informative)

        by Michael Woodhams ( 112247 ) on Wednesday March 02, 2005 @09:32PM (#11830473) Journal
        A fine summary, but I'm going to nit-pick on the order in which the experiments were done.

        What the double slit experiment did was allow us to show that light is both.

        The double slit experiment showed us that light was a wave. This understanding allowed a Grand Unified Theory of Optics (not that they called it that) which explained reflection, refraction and diffraction in terms of waves.

        We didn't know light was both until Einstein's 1905 paper on the photoelectric effect (for which he won his Nobel.)

        For electrons, it was the other way around. First we knew they were particles, then the electron double split experiment proved that they also behaved as waves.
    • Re:huh?! (Score:3, Insightful)

      by nihilogos ( 87025 )
      There's lots of explanations of the original double slit experiment, like this [qmw.ac.uk] and this [ntnu.edu.tw] (the second one is a java applet demonstration)

      This experiment was originally performed with light and proved that it behaved like a wave. Essentially when two waves combine you can get constructive interference when they pile up on top of each other, or destructive interference when they cancel each other out. This can be observed as an alternating pattern of light and dark on a screen or photographic film.

      Since 1905,
  • by Rosco P. Coltrane ( 209368 ) on Wednesday March 02, 2005 @06:11PM (#11828881)
    Do you guys get aspirine with your subscription? Cuz if you do, I'm signing up right now...
  • by American AC in Paris ( 230456 ) * on Wednesday March 02, 2005 @06:13PM (#11828906) Homepage
    Thomas Young's double-slit experiment is a classic experiment that helped establish the wave-like nature of light. Since then, it has been done with atoms, buckyballs, and biomolecules.

    Not to mention flowers [angryflower.com], too...

  • This sounds really cool and interesting, but I am not a particle/quantum physicist. Can someone who is possibly put this in laymans (or geeks) terms?

    • Re:WHAT? (Score:2, Insightful)

      by kavehkh ( 725943 )
      Yes.

      You can read more about the double-slit experiment at wikipedia [wikipedia.org].

      Similar intereference patterns(in time and space) are (relatively) trivial to do with light waves/particles. The other experiments mentioned in the article are instances were these are done with matter, and heavy matter for that matter.

      For this experiment, consider an atom that would be ionized, once a strong enough laser is shined[spell?] onto it. These guys, as I understand it, have crafted a laser pulse (think of it as a flow)
  • FYI (Score:3, Informative)

    by Scarblac ( 122480 ) <slashdot@gerlich.nl> on Wednesday March 02, 2005 @06:14PM (#11828912) Homepage

    "Maximum" is singular. "Maxima" is plural. Minima are similar.

    So it's "two maxima and one minimum."

  • Elegant (Score:5, Informative)

    by kickabear ( 173514 ) on Wednesday March 02, 2005 @06:14PM (#11828920) Homepage
    It's nice to see working physicists earn a chance to demonstrate something novel.

    For those of you who are unfamiliar with the double-slit experiment, there is a very clear, non-technical explanation here [utoronto.ca].

  • It's funny how one of the linked [physicsweb.org] articles refers back to this site they way this site refers to it. It's like when you have a mirror and you face it towards another mirror...

    ...only, Slashdot has never been "physicswebbed"...
  • So are they implying that time is a wave?

    That being the case, wouldn't that also imply that time is decoupled from space? IE - there is no space-time?

    It would seem that you can't measure time without measuring space. Of course, I'm not a physicist and I don't pretend to know what I'm talking about. So I'm sure I'm totally off base and misinterpreting the entire thing, I don't need to be told that in a vicious fasion, thank you. Please drive through.

    • What makes this interesting to me is that while we're used to seeing interference patterns from the intersection of two simultaneous phenomena, it's kind of bizarre to see intereference between two events that didn't even happen at the same time. If one event was over before the next event began, how can they interfere with each other?

      Of course, this was a question raised by the original experiment as well, I believe.

      Hrm.

      I think maybe I understand the nature of time even less than you do.
    • by Husgaard ( 858362 ) on Wednesday March 02, 2005 @06:44PM (#11829189)
      No, their experiment rather suggests that time is just another dimension like Einstein said.

      The experiment is the same as a known one, with a single difference: In the traditional experiment the slits are separated by a difference in the normal 3d space, But in this experiement the slices are at the same place in the normal 3d space but separated by a difference in time.

    • by Quantum Fizz ( 860218 ) on Wednesday March 02, 2005 @07:28PM (#11829581)
      So are they implying that time is a wave?

      No, time isn't a wave. As another poster mentioned, time is another dimension.

      But it's much more tricky than that, time is very different from space. If you rotate a vector in 3-D space, it's length (x^2+y^2+z^2) will remain the same, even though the x,y, and z components are different and kind of mixed together. What Einstein showed is that in 4-dimension space-time, the quantity (-t^2+x^2+y^2+z^2) is what is conserved if you 'rotate' in 4-D spacetime (in other words, if you change reference frames, like going from standing on the ground to standing on a freigh train). So spatial dimensions look spherical while the time dimension looks hyperbolic.

      There are obvious parallels between Space and Time in non-relativistic quantum mechanics, namely a time translation evolves the wavefunction by a factor exp(-i*H*t/hbar) and a spatial translation evolves the wavefunction by a factor exp(-i*p*x/hbar). What this means is that momentum is the 'generator' of space translations, and the 'Hamiltonian' is the generator of time translations.

      But making relativity works in quantum mechanics isn't as straightforward as physicists hoped, and involved alot of extra work, which finally culminated as quantum field theory. You can read more detail here [wikipedia.org]. But here's a quick summary :

      In quantum mechanics, position and momentum aren't just parameters but are operators. They don't commute, which is why you cannot simultaneously know a position and momentum. But time is NOT an operator, it is a parameter, it's the corresponding Hamiltonian that is the operator. So you have 4-dimensional space, 3 dimensions act like operators, 1 dimension acts as a parameter.

      So anyway, back to this experiment, what the physicists did was to show that an electron, with a probability of being created during two discrete times (each of the laser pulses) turns out to have an interference pattern just like photons traveling through two slits in space.

      The resulting electrons weren't produced from laser pulse 1 or laser pulse 2, but were produced from a superposition of both pulses, and the complex phase that I showed previously with time evolution causes an interference pattern between the two pulses.

  • Each maxima has a probability of ionizing an argon atom and producing an electron.

    Well, ya got to start somewhere.

  • Speaking of time... (Score:4, Interesting)

    by serutan ( 259622 ) <snoopdougNO@SPAMgeekazon.com> on Wednesday March 02, 2005 @06:24PM (#11829005) Homepage
    Relativistic time dilation has been demonstrated by synchronizing atomic clocks and sending one of them into space for a while at high speed. The one sent into space slows down a tiny bit. As I interpret this, one of the clocks is slightly in the past relative to the other one.

    Suppose you did the same thing with two entangled particles. The particle sent into orbit be slightly in the past relative to the other one. So would they then be entangled across the dimension of time? Seems like this has big implications, though what they are is beyond me.
    • The particle sent into orbit be slightly in the past relative to the other one. So would they then be entangled across the dimension of time?

      Firstly, you're not sending one particle in the past, it's that time just moves slower for that particle. You'd still have no way of sending information back in time to that person, everything would still be causal.

      Regarding the entangled particles, they would remain entangled, but now you have to resolve the problem of simultaneity. Ie, simultaneous events for m

    • "As I interpret this, one of the clocks is slightly in the past relative to the other one."

      Why? Both clocks are sitting side by side and can be viewed by the same individual at the same time. A simpler interpretation is that one clock experienced a slower time as demonstrated by it's time display in the here-and-now.

    • by nurbman ( 659852 )
      Too lazy to look it up but I seem to remember a thought experiment that someone cooked up where a photon is passed throug a gravitational lens a billion light years in the past. The problem was what if you were able to do a measurement now to collapse the wave? I seem to recall that someone prooved that this is the case: where the photon then appears to go back in time a billion years and choose which side of the lens to traverse. Anyone read about this?
      • I read in a book called "The Field" (by Lynne McTaggart), an even more amazing experiment, that showed that human consciousness could affect events in the past, as long as they hadn't been measured yet.

        They found that just about everyone could, on a small but repeatable level, affect the output of a random number generator just by concentrating on it. (The implications of that, if true, are staggering enough alone)

        So then they tried running the tests and sealing the results, and had the participants conc
        • by radtea ( 464814 )
          They found that just about everyone could, on a small but repeatable level, affect the output of a random number generator just by concentrating on it. (The implications of that, if true, are staggering enough alone)

          Extremely careful analysis is required when looking for very small effects in the midst of large masses of data.

          See for example: http://quasar.as.utexas.edu/papers/reg.pdf [utexas.edu]

          Frequentist analysis breaks down in a variety of circumstances, and Bayesian analysis must be used instead. The most f
  • "Whoa." --Neo (Score:3, Insightful)

    by game kid ( 805301 ) on Wednesday March 02, 2005 @06:25PM (#11829015) Homepage

    The very thought of making 5-femtosecond laser pulses (0.000 000 000 000 005 sec, right?) leaves me feeling dumb and slow.

    That aside, someone please clue me in here:

    The team was able to control the output of the laser so that all the pulses were identical. The researchers could, for example, ensure that each pulse contained two maxima of the electric field (thatis, two peaks with large positive values) and one minimum (a peak with a large negative value). There was a small probability that an atom would be ionized by one or other of the maxima, which therefore played the role of the slits, with the resulting electron being accelerated towards a detector. If the atom was ionized by the minimum, the electron travelled in the opposite direction towards a second detector.

    So if the electrons hit the laser when the pulse was at maximum strength they would hit the detector, like the two "beams" of light passed through the slits in Young's experiment? and the ones that pass "between" the maxima and minima get distorted like the blurry edges of the light? thus making "slits" of electrons but at instants in time instead of separate points? (I'm no physics expert but I'm sure you guessed that by now...)

  • hmmm... (Score:4, Funny)

    by dallask ( 320655 ) <codeninja@gmail.cERDOSom minus math_god> on Wednesday March 02, 2005 @06:26PM (#11829024) Homepage
    Im going to need alot of pot to understand this one.
  • by El_Smack ( 267329 ) on Wednesday March 02, 2005 @06:28PM (#11829042)

    I can understand the use of a Maxima [nissanusa.com], it's a solid car. But pairing it with a Minima (I think it's Kia's Minivan model, not sure) is just silly.
  • verbatim quote, I kid you not:

    is the interference of single electrons in a Young's double slit.

    Yeah, 'interference'... Young's double 'slit'.... where do I sign up? Some of the curves on the graph were not work safe!

    Is this porn for those who never see the light of day?
  • by Squeeze Truck ( 2971 ) <xmsho@yahoo.com> on Wednesday March 02, 2005 @06:31PM (#11829074) Homepage
    I thought the meaning of the double slit test was to prove that the single electron actually passed through both slits, and in essence interfered with itself.
    But in this case we're dealing with two different electrons fired at different times, so it's not quite the same.

    Even so, if the electrons create the interference pattern, that means they must have collided... in time? So the second electron reached the point of collision before it was actually fired.
    Does that mean that every electron travels every possible path in space AND in time? So whenever it is possible for an electron to be fired, it does, and interferes with all other electrons fired at all other times?

    My head hurts. Damn you, Science.
    • by gardyloo ( 512791 ) on Wednesday March 02, 2005 @06:44PM (#11829183)
      Does that mean that every electron travels every possible path in space AND in time? So whenever it is possible for an electron to be fired, it does, and interferes with all other electrons fired at all other times?

      Basically, yup. Read Feynman's QED. He claims (and the math and experiments bear him out thus far) that all photons are particles, all electrons are particles, etc., and that this "all possible paths" concept is what accounts for their "wavelike" manifestations.
  • So.... (Score:2, Funny)

    by greenegg77 ( 718749 )
    Did they find out the result before they did the experiment?
    There's gotta be a Bill & Ted quote in there somewhere.
  • This is nothing compared to the Unification of Electromagnetic and Gravitational theories. It has been done and the results can be found here [singtech.com].

    Or so I've been told. The book explaining the theory is ~$26USD.

  • Interesting (Score:5, Interesting)

    by Husgaard ( 858362 ) on Wednesday March 02, 2005 @06:33PM (#11829099)
    I am not a physicist, but a bit interested in stuff like this.

    Looks to be that they have redone the classic double-slit experiment in a new variation.

    Instead of having the two slits existing at the same time but in different 3d space, they made the slits in different time, but in same 3d space.

    Probably we have the same quantum effect as in the traditional double-slit experiment: When trying to determine which slit the particle passes through the interference pattern goes away, as the waves change change to particles.

    It doesn't look to me like they have seen that experimentally yet. Their setup that did not produce the interference pattern looks more like a single-slit to me.

    But I think that an attempt to find out at which of the two maxima are ionizing an argon atom should make the interference pattern go away.

  • pi in the sky (Score:4, Interesting)

    by Doc Ruby ( 173196 ) on Wednesday March 02, 2005 @06:39PM (#11829144) Homepage Journal
    I'd love to see a geometric illustration of how this demonstration is identical to Young's, rotated in spacetime.
  • Sounds (as much as this layman can determine) quite a lot like the process used in Michael Crichton's novel Timeline [crichton-official.com].
  • by wcrowe ( 94389 ) on Wednesday March 02, 2005 @06:44PM (#11829188)
    ...how can we turn this into some sort of weapon?

  • Bob [angryflower.com] did it first...
  • A Brief Explanation (Score:5, Informative)

    by MAdMaxOr ( 834679 ) on Wednesday March 02, 2005 @06:49PM (#11829235)
    **Skip the first part if you know the basics.

    If you pass a water wave through a wall with two slits in it, you will get interference. If you put another solid wall (no slits) beyond and parallel to the first wall, you will see that the water line on the 2nd wall looks like a sinewave with magnitude tapering off as you get further from the slits.

    If you pass particles (electrons, photons, etc) at a wall with two slits, and place a "detecting wall" beyond the first wall, then the distribution of electrons hitting the detecting wall would be similar to the wave observed against the 2nd wall in the water example.

    --New Experiment--

    In the new example, two pulses of light can trigger an electron to be released. Think of these two pulses as pulling a trigger on a gun while playing russian roulette. The electron is the bullet and the detector is your head. If you pulled the trigger at 0 secs and 2 secs, you'd expect to see a person die at 0.01 seconds and/or/neither 2.01 seconds, assuming it took 0.01 seconds for the bullet to reach the person and kill him.

    The detector, however sees an interference pattern. This is like seeing deaths at 1 second or 1.5 seconds. The interference pattern is measured as a function of time, and instead of seeing two blips in time, they saw a range.
  • by MosesJones ( 55544 ) on Wednesday March 02, 2005 @06:53PM (#11829263) Homepage
    First there was Chinese relativity

    "All of your problems, no matter how big or small, 1.2 billion chinese people could give a fuck"

    and then there was relative relativity

    "No matter what your achievements, your aunt will continue to tell your girlfriend/wife about the time when you ran nude in the garden aged 5"

    and now I bring you the Scientific relativity theory

    "No matter how smart you think you are, you still look smart to a time splitting physicist"

  • by jd ( 1658 ) <imipakNO@SPAMyahoo.com> on Wednesday March 02, 2005 @07:08PM (#11829414) Homepage Journal
    Babelfish hasn't got a translator for this, yet, so I'm only guessing here. When two waves interact, they can either reinforce each other or they can cancel each other out. These are called constructive and destructive interference, respectively.


    To demonstrate this, find a sink with two distinct taps. Half-fill the sink with water. Now, turn the taps so that the water drips out slowly from each. You will see ripples spreading out from where the drops strike the water. You'll also see that where the ripples cross, there are light patches, dark patches and some areas that seem to be smooth.


    The light and dark patches are where you have constructive interference. If you have a trough, then the trough is deeper than normal and hence appears dark. If you have a peak, the peak is higher than normal and appears light.


    the "double slit" experiment was devised by your typical mad scientist. The idea is simple enough. You direct a stream of photons at one of two very narrow gaps. You then have some sort of screen on the other side for the light to shine on. If photons are just particles, then they will go through that one gap and show up as a single spot on the other side.


    If, however, particles are waves, they will go through BOTH gaps. The waves will then interfere with each other, as in the sink experiment above, and you'll see patches of light and dark on the other side.


    What you get is patches of light and dark, showing that light behaves like a wave.


    Now it gets really fun. Turn down the light source. If light is a wave, you expect the same interference pattern, only dimmer. Err, no. What happens is that you start getting a speckled pattern. Eventually, the bands dissolve entirely and you just get a single spot. This proves that light is a particle.


    There are a number of ways to resolve this apparent paradox. The simplest is to say that light is a particle that can exist anywhere in the wave with a given probability. With enough particles of light, you see a complete wave, because every possible part of the wave is occupied. With insufficient particles, you get an incomplete wave, and therefore the incomplete interference pattern that you observe.


    Now we've got the spacial part over with, we move onto time.


    The experiment demonstrates several things. Firstly, it demonstrates that time behaves in a similar manner to space, with regards to objects travelling through it. This will really irritate physicists who have argued that although time and space are coupled, as per Einstein's space/time model, time was not a dimension in the sense that spacial dimensions were. That's going to be a much harder line of reasoning to maintain, now, because clearly time DOES behave in the same way as a spacial dimension, when it comes to diffraction.


    The second - and more important - thing that is shown here is that objects do not just have a probability of existing in a specific point in space, they ALSO have a probability of existing in a specific point in time.


    Other than causing Professor Hawking a whole bunch of headaches, I don't see this new observation as doing a whole lot. There may be a way to exploit the technique to generate an animated hologram, though, as you'd have a way of influencing interference patterns with respect to time from a single image, but that's about it.

    • ...time was not a dimension in the sense that spacial dimensions were. That's going to be a much harder line of reasoning to maintain, now, because clearly time DOES behave in the same way as a spacial dimension, when it comes to diffraction.

      I don't think this has anything to do with the properties of time per se. As I understood the effect, it has to do with the spatial "probability field" of tiny objects. If there is *any* uncertainty which path a small object will take, the entire probable space will a
  • by Nicky G ( 859089 ) on Wednesday March 02, 2005 @07:14PM (#11829456)
    This seems pretty significant to me, as a layperson. I always personally interpretted the classic double slit experiement as indicatiing "time" as we know it -- linear time, from moment to moment... Is BS. And perhaps, all time exists simultaneously, and it is the singularity of our consciousness that focuses it into a linear progression.

    It's too bad more laypeople don't get into quantum physics, string theory, etc. The implicatisons are pretty amazing on both scientific and spiritual levels, and I have chosen to read much of what this science tells us as: The Universe (Multiverse) is One and Many simultaneously, we are all a part of it, and in essence, are all One. Time is an illusion on the ultimate level, as is the notion of our matter and energy being separate from every other element of the universe. Thus, death as we know it does not truly exist, when what you are is a focal point of the neverending Multiverse (God, if you wanna put it that way -- but that's up to you).

    Gee... I wonder why they don't teach any of this stuff in the school system, unless you happen to go into phsyics?

    I highly recommend The Tao of Physics by Capra (which I'm sure many scientists loathe). Also writings by Nick Herbert are pretty interesting. A lot of the stuff we are finding equations for now is what many indegenous cultures have taught for thousands and thousands of years. They may have communicated the ideas differently, but they strike me as having the same message.

    ---

    The techno-mediated cultural conspiracy

    http://thewired.blogs.com/teotwawki/

  • by null etc. ( 524767 ) on Wednesday March 02, 2005 @07:23PM (#11829539)
    This has enormous ramifications for the lay person. Let me break it down.

    The "slit" was a crafted femtosecond pulse consisting of one-and-a-half cycles--say, two maxima and one minima--passed through an argon gas.

    Anyone who has a femtosecond pulse generator should feel comfortable with this. If not, get access to a two-photon UV femtosecond pulse generator which uses nanosecond-time-scale infrared laser to deplete the terminal state of an F2 laser, based on F2 transitions.

    Next, you'll want a healthy dose of argon gas. Argon is used to reduce heat loss in sealed units by slowing down convection inside the air space. You can get argon gas cartridges to prevent wine oxidation, which is a neat little side benefit. A 50L cylinder filled with argon gas to a pressure of 10130 kPa at 30C has approximately 201 moles of argon. Just remember that if you're going to lase with argon, its most efficient transitions are at 488 nm and 514.5 nm.

    So now you'll need to create an ion chamber using the argon gas. You'll need a metal conducting can, and a wire electrode in the center which is well insulated from the chamber walls. The chamber, of course, will be filled with argon.

    Next, you'll need to use your femtosecond pulse generator to apply a DC voltage between the outer can and center electrode. This will create an electric field, of only a few volts, that sweeps the ions to the oppositely charged electrodes. For some additional fun, if you apply a few hundred volts, the electron emissions will produce "secondary emissions", which amplify the results. I wouldn't recommend creating one of these by hand if you haven't already done so, but remember to use a 4.7uF capacitor with non-polar film, a 100,000 megohm resistor and a 2N4117A electrometer-grade JFET.

    Anyways, generating a local maxima shouldn't be too difficult if you keep the phase dynamics of your pulse generator within one half delta of the wavelength propogation delay of your argon gas cylinder. This, as always, varies according to room temperature, so be sure to calibrate your scales before attempting the experiment.

    The trickiest part of the experiment is to build a ray tube to display your intereference pattern. I suggest using a Tektronix Type 453 Oscilloscope, which may be hard to find but has the best bang per buck.

    In no time at all, you'll be generating double slits in time!

    • In no time at all, you'll be generating double slits in time!

      Shouldn't that be, "In no space at all, you'll be generating double slits in time" ?

  • by Richard Kirk ( 535523 ) on Thursday March 03, 2005 @04:30AM (#11832167)
    The transmission electron microscope (or TEM) is not the gadget that gives the lovely looking photographs of 3D objects - that's a scanning electron microscope (or SEM). The transmission electron microscope passes a beam of highly collimated electrons though a thin film sample, and then projects the beam onto a phosphor screen at the bottom of the column, much like a slide projector for electrons. The TEM is a lot simpler than the SEM, and it used to be the standard way of getting a really close look at your microstructure back in the 1970's, if you could make it thin enough, and avoid it getting cooked by the electrons.

    You actually see the image on the phosphor screen yourself through a window at the base of the column. The image is a bit dim, you you have to have the lights out, but what you see is being imaged directly.

    The electrons all have roughly the same energy - a million eV or so - so they are the equivalent of nearly monochromatic light. If your target film varies in thickness, then you get electron Newton's rings because of reflections from the top and bottom surfaces. You can get lots of fringes - out to the 50th or 100th order because the electrons are pretty monochromatic.

    Suppose you have a 1 MeV electron beam travelling about 50 cms from your target to the screen. You cannot put more than a few hundred picoamps through your target without frying it. Now you do not get many electrons per second in a picoamp, and they are moving very fast at 1 MeV. I remember doing the sums, and finding out that the whole TEM column for my beam current spent 97% of its time completely empty. The film is only a few nm of this 50 cms, so the odds of it having two transmitting electrons in it at once is really tiny.

    You actually see the image on the phosphor screen yourself through a window at the base of the column. The image is a bit dim, so you you have to have all the lights out, but what you see is being imaged directly by the electrons. Or electron, rather, because what you are looking it is the image formed by a single electron interfering fifty or a hundred times with itself after having passed through every point of the target film, and reflecting (or not reflecting) multiple times off each surface.

    This as much as anything got me to believe in the wave equations. Trust in the sums and leave your common sense by the door, and it all seems to work.

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