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Super-fast Transistors On the Way

Posted by ryuzaki0 on from the life-in-the-fast-lane dept.

nbannerman writes "The BBC is reporting about a new kind of transistor, that recently set a world record of 110Ghz. From the article: 'To achieve the speed gain, researchers at the University of Southampton added fluorine to the silicon devices. The technique uses existing silicon manufacturing technology meaning it should be quick and easy to deploy.' The apparent applications for this process include mobile phones and digital cameras."

32 of 172 comments (clear)

  1. Faster? by Asm-Coder · · Score: 4, Insightful

    Maybe we should just get faster software.

    1. Re:Faster? by rsilvergun · · Score: 4, Insightful

      It's cheaper to pay a few top engineers to make faster hardware then to pay a mountain of top computer scientists to write stable, fast code. Corel learned that the hardway.

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    2. Re:Faster? by Jah-Wren+Ryel · · Score: 5, Funny

      It's cheaper to pay a few top engineers to make faster hardware then to pay a mountain of top computer scientists to write stable, fast code.

      Yeah, because if the cpu is fast enough, even unstable code works better!

      --
      When information is power, privacy is freedom.
    3. Re:Faster? by Carthag · · Score: 4, Insightful

      It's the old "stable, fast, on schedule; pick two" -- the faster the chip is, the more likely you can concentrate on writing stable code on schedule and make up for the slowness with processor speed.

  2. Mobile Phones? by terminateprocess · · Score: 3, Funny

    Now remind me why exactly we need 110GhZ moblie phone processors?

    --
    int cents = 0;
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    1. Re:Mobile Phones? by Formica · · Score: 5, Informative

      They're talking about transistors, not entire processors. High speed transistors are needed for the RF front-end, where analog signals up to 1 GHz or so are encountered. These signals require devices that can switch at speeds significantly faster than the signal frequency. Formica

    2. Re:Mobile Phones? by Trouvist · · Score: 5, Informative

      The faster the chip cycles, the higher the communication frequency can be. It is difficult to do noise-reduction calculations on ultra-high frequency communications without chips that cycle at the rate of data transmission.

    3. Re:Mobile Phones? by Anonymous Coward · · Score: 5, Insightful

      So my shiny new video-enabled phone will respond instantaneously to button-presses.

      Like my LCD-based phones from 10 years ago used to.

    4. Re:Mobile Phones? by Formica · · Score: 3, Informative

      11 GHz chip != 11 GHz processor. They're mainly talking about analog chips - i.e. op-amps, oscillators, high speed muxes, etc. Chips like these: http://www.maxim-ic.com/solutions/cellular_handset s/index.mvp?pl_pk=14 http://www.analog.com/en/subCat/0,2879,770%255F851 %255F0%255F%255F0%255F,00.html

    5. Re:Mobile Phones? by Anonymous Coward · · Score: 4, Funny

      Now that you posted the misinformation, Microsoft will raise their system requirements beyond what processors are capa.....

      On second thought, post all kinds of misinformation like this, then Microsoft will spec themselves out of business. ;)

    6. Re:Mobile Phones? by swg101 · · Score: 5, Informative

      Actually, the article says that they created a BJT transistor
      "The research was carried out using a simple type of transistor known as a silicon bipolar transistor."
      Processors use FET transistors because BJT transistors need current to bias them all the time. These transistors would consume way too much power to make any sort of processor (especially for mobile devices). As others have commented, this would only be useful for the analog processing of the output transmitter.

      --
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    7. Re:Mobile Phones? by ozmanjusri · · Score: 4, Funny
      it's GHz not GhZ, you babboon.

      It's baboon not babboon, you buffoon.

      --
      "I've got more toys than Teruhisa Kitahara."
  3. As an added benefit... by nebaz · · Score: 5, Funny

    added fluorine to the silicon devices

    Not only will the transistors be faster, but whiter and shinier, they won't need to floss.

    --
    Rhymes that keep their secrets will unfold behind the clouds.There upon the rainbow is the answer to a neverending story
    1. Re:As an added benefit... by GeckoX · · Score: 4, Informative

      Um, sure, but you've got the wrong substance in mind.

      Fluorine: http://en.wikipedia.org/wiki/Fluorine

      Fluoride: http://en.wikipedia.org/wiki/Fluoride

      There would be some pretty serious differences betweent the two. Neither is good for you to ingest, but one is just REALLY BAD to get anywhere near you at all!

      --
      No Comment.
  4. But use of such mobile phones and cameras... by Anonymous Coward · · Score: 5, Funny

    ...might taint your precious bodily fluids.

  5. Real-world benefits? by FlyByPC · · Score: 3, Funny

    ...so this means that Flight Simulator X will run at 10fps instead of 5?

    --
    Paleotechnologist and connoisseur of pretty shiny things.
  6. Re:These are bipolar devices by NotQuiteReal · · Score: 5, Funny

    Couldn't they add some Lithium too?

    --
    This issue is a bit more complicated than you think.
  7. Power Consumption by grahamsz · · Score: 3, Interesting

    Remember that when a CMOS gate is switching the current flowing through it increases. The faster the gate is able to switch, the less power will be used in the state change. Now the processor doesn't have to run at anywhere near that speed, but the fast transistor switch will minimize the power per cycle.

    1. Re:Power Consumption by dunkers · · Score: 3, Informative

      The gate will only switch faster for the same, or less, current if the gate capacitance is decreased - i.e. you make the device physically smaller. If the capacitance stays the same then you must bung in current faster to achieve faster switching. Faster switching may reduce the power cycle (time), but on its own it doesn't reduce the power requirements.

    2. Re:Power Consumption by dpilot · · Score: 4, Informative

      You're both right.

      You are talking about basic c*v**2 current, and he's talking about shoot-through current during the transition. Though one normally doesn't fuss too hard about shoot-through unless slew rates are really slow. But then again, it wasn't that many years ago that device standby leakage was nearly negligible, instead of being a substantial fraction of the active current, like it is today. For that matter, the scope traces I've seen of high-speed clocks look a heck of a lot more like a sine wave than a logic pulse, but at this point we're stressing capabilities of the measurment electonics, too.

      --
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    3. Re:Power Consumption by wontonenigma · · Score: 5, Informative
      From the article:
      The research was carried out using a simple type of transistor known as a silicon bipolar transistor.
      RTFA

      This isn't about CMOS, for a change. This is about analog power amplification and the 100GHz figure quoted is either the maximum frequency of current or power amplification. Too bad the BBC doesn't say.

      Most cell phones contain one Gallium Arsenide bipolar transistor to amplify the signal going to the antenna. This faster Silicon transistor would open up other transmission frequencies but it wouldn't make that game of Alchemy play any faster.
      --
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    4. Re:Power Consumption by 1zenerdiode · · Score: 4, Informative

      Yeah, except TFA says the gains were achieved with modified BJT technology, which is not CMOS. In addition, the faster that you switch COMPLIMENTARY (that's the C) MOS structures, the larger the shoot-through current (this is the current that flows between the power supply rails as each transistor in the complimentary structure is temporarily partially conducting). In microprocessors and memory cells, these are responsible for huge transient current requirements, and get worse as the clock frequency is increased.

      The reason that the development is significant is not from a microprocessor standpoint - it means that the front end amplifiers and mixers that have to run at the highest frequencies can be fabricated using more cost-effective manufacturing techniques. This is assuming that the article is correct in stating the development concerns BJT's. Hell knows why they showed a photo of a non-populated circuit board, but hey, it's the media. Guess you have dial your expectations lower.

  8. Mod the parent upwards! by Anonymous Coward · · Score: 3, Funny
    So the future will get here faster.


    Precisely! We agree completely.

    Signed,
    SACFTF
    Slashdot Anonymous Cowards For The Future

    -----EQUAL REPRESENTATION-----

    Listen you "big A-C" Anonymous Cowards, we're against the future. Technology ruined our lives, remember when trolls used to live under bridges? Now we live in basements or apartments. We should go backwards, not forwards!

    Signed,
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    Slashdot Anonymous Cowards Against The Future.
  9. Re:bipolar transistors by Andy+Dodd · · Score: 5, Informative

    No, because whenever Slashdot covers these ultra-high-frequency transistors, they never bother mentioning that there's a huge difference between transistors optimized for logic (always on/off, usually very high drive levels and low gain, fast switching of square waves) and transistors designed for RF signal amplification (Usually designed for linear amplification of sinusoidal or modulated sinusoidal signals, lower drive levels with higher gain, and no one cares about the switching time, just the highest frequency sinusoid at which the device exhibits gain.) In essentially every case, the article is covering amplification of a signal at the record-setting frequency, not operation of a logic gate at that frequency.

    There is also a very good chance that while the manufacturing process may be suitable for single (relatively) large tranistors (perfectly suitable, and often desireable for RF), it is not suitable for integrated circuits with multiple tranistors and other components on a die. Gallium Arsenide is a perfect example of this - The IC industry gave up on it pretty quickly because it was simply too difficult to make integrated circuits with it and the performance benefits for logic circuits weren't worth the costs, but manufacturers of RF transistors are still putting large amounts of effort into GaAs and plenty of commercial products exist. (Yes, there are still issues with GaAs technology and a lot of companies still don't trust GaAs in their products except in low-volume high-performance applications, but it's not like logic circuits where nothing exists on the market.)

    Same thing with IBM's big SiGe push - great for RF but doesn't seem to have made any inroads to logic, probably due to cost issues and technical problems that make SiGe potentially unsuitable for logic but don't really affect their RF performance.

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  10. Re:bipolar transistors by Andy+Dodd · · Score: 4, Informative

    And before anyone brings up that TFA does mention "clocking", the impression I get is that the writer of the article isn't very technically literate and doesn't really understand the difference between RF circuitry and clocked logic circuitry. See the comment about mobile phones operating in the 1 GHz range - even the fastest smartphones have a CPU clock speed of only 400-500 MHz at most, but mobile phones have been operating with RF carriers close to 1 GHz (specifically 800 and 900 MHz) for 15-20 years, and the 1.8 and 1.9 GHz bands have been in use for close to a decade too. Satellite communications systems frequently operate in the 10-20 GHz region. I don't see any case where the researchers are directly quoted talking about using their new developments for logic circuitry, but a few where they are implying using the new stuff for RF.

    --
    retrorocket.o not found, launch anyway?
  11. MOSFET Application by dduardo · · Score: 4, Informative

    I believe this technique would speed up MOSFETs as well because they are saying that the added fluorine doesn't allow the boron to diffuse into the silcon as much. This means you'll have a cleaner line between the p-type and n-type dopped regions. In terms of MOSFETs you could inject the flourine under the gate so when you dope the silicon to create the source and drain you won't have overlap you normaly get under the gate. This means you could reduce the gate to drain and gate to source capacitances which kills the high frequencies.

    1. Re:MOSFET Application by dcapel · · Score: 5, Funny

      Truely now, how many people modded this insightful because they didn't understand it?

      --
      DYWYPI?
    2. Re:MOSFET Application by strider44 · · Score: 4, Informative

      Two. The other two people who modded it modded it informative because they didn't understand it.

    3. Re:MOSFET Application by Aceticon · · Score: 4, Informative

      A MOSFET is a type of transistor which is very common in integrated circuits because it's very easy to make using the most common IC fabrication techniques (which basically boil down to making holes in a silicon base, filling those holes with stuff and depositing lines of other stuff on top of it).

      One of the physical features of a MOSFET is that there are places where silicon dopped to be of the type P (ie, a substance was added to it so that it is missing electrons in it's crystaline structure by comparisson with pure silicon) is in direct contact with silicon dopped to be of type N (ie, a substance was added to it so that it has extra electrons in it's crystaline structure by comparisson with pure silicon).

      Now, as many of us know, solids are just very slow liquids ... stuff embedded in a solid tends to move around, though slowly. The higher the temperature, the faster the moving.

      In the specific case of a MOSFET, we have junctions between the silicon dopped with a specific material to make it type-N (ie more electrons) and silicon dopped with a different material to make it type-P (ie fewer electrons). In this situation, some of the dopping atoms in the type-N silicon will move to the type-P side and vice versa, thus making the junction less "sharp" (in terms of the difference between both sides).

      Some very complicated formulas (which i forgot all about) can be used to show that the "sharper" the junction, the more efficient it is.

      This is what the GGP is going about.

      Consider that maybe there are enough people in /. with an EE degree or a deep interest in electronics to actually understand the issue at hand, and maybe, just maybe, they're extra attracted to articles about new kinds of transistors !!???

  12. Not really the fastest transistor... by Manchot · · Score: 4, Informative

    Sure, it might be the fastest silicon BJT, but as TFA alludes to, there are InGaAs HBTs that are functionally equivalent to BJTs and have cutoff frequencies of 710 GHz. Specifically, I'm talking about the one discussed in this paper by Milton Feng's group at the University of Illinois.

  13. OMG that would be hard to use. by Anonymous Coward · · Score: 3, Interesting

    At 100 GHz the wavelength is 3 cm. A quarter wave line would be 0.75 cm. This thing is operating at a frequency well above that at which it is easy/feasible to use a printed circuit board. To operate at this frequency I would have to spend a whole pile of money so I could use hybrid IC techniques. Or I could figure out how to couple this device to waveguide. AARGH!

    The magic word Slashdot asks me to type to prove that I'm not a robot is 'hospital'. How very appropriate 'cause that's where I would end up if I tried to use this sucker.

  14. What About IBM+Georgia Tech @ 500ghz? by raftpeople · · Score: 4, Informative

    Just a few weeks ago there was an article about IBM in conjunction with Georgia Tech, supercooled reaching 500ghz, room temp was at about 300ghz.

    Hos is this new one a world record at 110ghz?