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Intel Announces Laser Breakthrough

Posted by ryuzaki0 on from the speed-of-light dept.

AdmiralWeirdbeard writes "Intel has just announced a breakthrough in laser technology allowing a continuous laser wave on a silicon chip. Apparently they devised a method to sap the interfering field of electrons previously generated in silicon by the lasers. Intel says that hardware exploiting the advance might begin appearing at the end of the decade."

15 of 185 comments (clear)

  1. Re:Correct Units? by Anonymous Coward · · Score: 5, Informative

    The (first) article states the waveguide is 1.5x1.55micrometers and 48millimeters in length, Has it got the units right on that one?

    No, those units look right. If you really read the first article, then you would have seen the picture of the die.

  2. Expensive? by BeerCat · · Score: 5, Insightful

    From TFA: The Santa Clara, Calif.-based company has created a chip containing eight continuous Raman lasers by using fairly standard silicon processes rather than the somewhat expensive materials and processes required for making lasers today.

    OK, so I'm probably missing some major point here, but, define "expensive" for making lasers, given that there is a laser in every cheap £20 CD player, cheap £30 DVD player, cheap £5 laser pointer... Can't be that expensive, surely?

    --
    "She's furniture with a pulse"
    1. Re:Expensive? by thpr · · Score: 5, Informative
      define "expensive" for making lasers

      Keep in mind that the lasers you are working with are not very precise (the CD player, DVD player), or even only have to be coherent (the laser pointer) and not pulsing. Even with the encoding, the DVD is only transmitting a few Mb/s of information as it encounters pits and lands on a CD/DVD. (4.7GB/2 hours = ~6Mb/s)

      The long-haul optical systems and optical switches are transmitting over multi-kilometer fiber optic cable that is transmitting at Gb/s rates. That requires a MUCH better laser, in terms of power, coherency and switching speed. I actually don't know what the lasers cost, but some of the receivers can be in the hundreds for a single receiver at the very high end. The optical systems themselves are rather expensive, being thousands of dollars for a single mid-range board that has a pair of optical receiver/transmitters (2 ports).

  3. Re:Correct Units? by k98sven · · Score: 5, Informative

    The (first) article states the waveguide is 1.5x1.55micrometers and 48millimeters in length, Has it got the units right on that one?

    Yes. The Nature article the guys published (20 Jan, vol 433, p292) on this says "4.8 cm".

    IANAEE, so maybe its correct, but their going to refine it, or maybe its not linear.

    Yes, of course they're going to develop this further. This is the first time they've achived continous-wave laser gain in silicon, obviously the next step is to increase it.
    (A smaller cavity requires larger gain)

    No it's not linear, the cavity is S-shaped.

  4. End of the Decade? by Bingo+Foo · · Score: 5, Funny
    Intel says that hardware exploiting the advance might begin appearing at the end of the decade.

    Which one?

    --
    taken! (by Davidleeroth) Thanks Bingo Foo!
  5. What in the... by d474 · · Score: 5, Funny
    From TFA:
    1. Rong's chip produces laser light when it is 'pumped' with another laser.

    I'm sorry, but that is just Rong...
    --
    Authority questions you. Return the favor.
    1. Re:What in the... by d474 · · Score: 4, Funny
      Wait a minute, wait a minute...
      1. Rong's chip produces laser light when it is 'pumped' with another laser.
      So, two lights make a Rong?
      --
      Authority questions you. Return the favor.
    2. Re:What in the... by Some_Llama · · Score: 5, Funny

      "Wait a minute, wait a minute...

      Rong's chip produces laser light when it is 'pumped' with another laser.

      So, two lights make a Rong?"

      No it means it will Lase you rong time...

  6. Do you smell that? by eomnimedia · · Score: 4, Funny

    "...continuous laser wave..."

    Aw, nuts. And I just bought my new Continuous Bacon Wave . <sigh>There's always an upgrade.</sigh>

    1. Re:Do you smell that? by wildsurf · · Score: 4, Funny

      Aw, nuts. And I just bought my new Continuous Bacon Wave.

      That sounds like it would be useful for Ham Radio.

      --
      Weeks of coding saves hours of planning.
  7. No... by maynard · · Score: 5, Funny
    "[..]the potential implications for breast implants!"

    ...that's Silicone, not Silicon. BIG difference. Not the lease of which is feel. Imagine your wife with a hard and lumpy P4 in there, instead of a Silicone Gel breast implant, and you'll get the idea. Oh wait, yeah... some weirdos around here would dig that. Nevermind! *ahem!*--M

    1. Re:No... by ikkonoishi · · Score: 4, Funny

      My imaginary wife uses AMD you insensitive clod.

  8. Re:Am I the only one that doesn't get it? by thpr · · Score: 4, Interesting
    There are probably two major uses. The first is in an optical switch. Traditionally, switches were OEO (optical-electrical-optical) until the all-optical craze hit in 2000. OOO (all optical) are (in theory) able to switch the light faster, which reduces latency, power usage, and lots of other things in the optical core of the network. However, if you eliminate the separate optics devices and can run the optics directly onto the semiconductor, OEO may be a lot more competitive (meaning cheaper). Go search LightReading for "OEO" or "OOO" to follow that debate (of whether there is benefit to all-optical and the current state of the art. [Infinera is a rather interesting startup driving OEO into the future to compete with OOO]

    The second major use would be chip-to-chip interconnect. However, this becomes a challenge, as you try to keep a ribbon of fiber-optics (think 200-2000 strands) perfectly lined up with the lasers on the die. I'm not saying it can't be done, but it is one of the hurdles to face before it could be used that way in mass-produced systems like a PC. The theory goes that at about 1 foot per second, electrical propagation between chips is causing us lots of headaches. HyperTransport and other technologies make some advances to get around the plain limits, but there are still major problems with sending high-speed signals on circuit boards. Even if this can't help speed up absolute memory access time, it could help to improve throughput between memory and the processor, helping to avoid some of the single-threaded bottlenecks that led IBM and its partners to develop Cell

  9. Re:Catch 22 by Anztac · · Score: 5, Informative

    Yeah, they mention in the news.com article that silicon is a poor producer of light, what it is good at though is amplifying it via the Ramen effect.

    A Raman laser, in some ways, is ideally suited for silicon. The Raman Effect, discovered in 1928 by Nobel laureate Chandrasekhara Venkata Raman, roughly works as follows: Light hits a substance, causing the atoms in the substance to vibrate. The collision causes some of the photons to gain or lose energy, resulting in a secondary light of a different wavelength. A Raman laser essentially involves taking this secondary light and then amplifying it (by reflecting it and pumping energy into the system) to emit a functional beam. Because of its crystalline structure, silicon atoms readily vibrate when hit with light. The Raman Effect, in fact, is 10,000 times stronger in silicon than standard glass, which should make it far easier to amplify.

    --
    ~Anztac
  10. Re:But it's not a laser by Biff+Stu · · Score: 4, Informative

    Try learning physics.

    Laser: Light Amplification by Stimulated Emission of Radiation.

    The stimulated Raman effect is fundamentally different from stimulated emission. You can't get stimulated emission from Si because it is an indirect bandgap semiconductor. However, it is true that both processes can generate coherent beams of light, and people typically refer to devices that generate coherent light as laser sources, hence the term "Raman Laser".

    However, my point is that this device can't convert non-optical energy into optical energy. Furthermore, since it's a non-linear optical process, you can only get the necessary intinsity to drive this process from a coherent source. Therefore you must have an actual laser to start this process. This is something that they state in the articles. However, in the c/net article, the marketing hype starts to take over. They state, "The Santa Clara, Calif.-based company has created a chip containing eight continuous Raman lasers by using fairly standard silicon processes rather than the somewhat expensive materials and processes required for making lasers today." Implying that this gets us away needing old-fashoned expensive lasers. It doesn't.

    Yes, they are nice, small coherent light sources that can be easily modulated and integrated into Si, but they aren't lasers, and the efficiency is a problem.

    Let's say you want to start making integrated optical circuits. If you want a chip with 100 switches, you must pump each switch with 300 mW. (Well maybe you could cut back to 100 mW, but the efficiency of these things is non-linear, and there will be a threshold power at which they don't work.) Therefore, a device with just 100 switches would require 10 to 30 watts of coherent optical power to drive it. Then you need to worry about the wall-plug efficiency of your pump laser (or lasers) and the bulk of the pump laser.

    It's interesting, and it did deserve an article in Nature. However, there's a lot of corporate marketing hype behind all the buzz in the linked articles, and when marketing hype and science mix I get annoyed.