Intel compound could keep Moore's Law alive

CNet News UK ^ | 7 December 2005 | Michael Kanellos

[ShadowAce]

Intel plans to unfurl a prototype transistor this week that could help Moore's Law -- and the semiconductor industry as a whole -- continue to advance in the next decade.

The transistor, designed by Intel and Britain's QinetiQ, is similar in structure to a traditional transistor in that it comes with a source (the place where electrons start) and a drain (their final destination) connected by a channel. A gate controls the flow of electrons across the channel; acutely controlling this flow from the source and drain determines the ones and zeros of computing.

But, unlike in traditional transistors, the channel isn't made from silicon. Instead, it consists of indium antimonide, a compound made from the elements indium (In) and anitmony (Sb). In chemical terms, the two elements are known as III-V elements because of the row where they appear on the Periodic Table of the Elements. Silicon -- Si -- appears in column IV. The proximity means that indium and antimony share some characteristics with silicon, but still behave differently.

Intel says that replacing silicon with indium antimonide cuts power consumption by ten times while boosting performance by 50 per cent.

Just as important, III-V materials can potentially be grafted onto established manufacturing processes. This could make transistors easier and more economical to adopt for mass manufacturing than concepts like carbon nanotube transistors and silicon nanowires.

Chips featuring these transistors could hit the market by 2015, an Intel spokesman said. The experimental transistors right now rest on a substrate of gallium arsenide, an expensive material used in some communication chips. The company will next try to plant these III-V transistors onto a silicon substrate.

Intel has said before that III-V materials are one of the leading ideas for keeping Moore's Law alive. The famous dictum states that the number of transistors on a chip can be doubled every two years. This doubling is largely accomplished by shrinking the size of the transistors and leads to gains in performance. Smaller transistors, however, leak electricity and dissipate heat, two major problems for computer manufacturers and chip designers. Leakage and heat have, in turn, prompted researchers to seek out new materials and transistor structures to counter these aftereffects.

Intel and QinetiQ have shown off a similar III-V transistor before with a channel length of 200 nanometres. The transistor described in this week's paper measures 85 nanometres in length. Chips now made on the 90-nanometre process sport gates that stretch approximately 50 nanometres.

The paper describing the transistor will be presented on Wednesday at the International Electron Devices Meeting in Washington, DC.

[ShadowAce]

[2 Kool 2 Be 4-Gotten]

No point in buying new hardware now - might as well wait for 2015 when these babies come online.

[ozoneliar]

Any innovation by an American company is good news.

[Boundless]

See also earlier thread:
Intel Announces Chip Technology Breakthrough Using New Materials
http://www.freerepublic.com/focus/f-news/1535698/posts

The Register, at:
Intel, Qinetiq tout quantum well transistor breakthrough
http://www.theregister.co.uk/2005/12/07/intel_qinetiq_quantum_well/
has a subtitle of: "0.5V, 300GHz CPU, anyone?"

Now 300 GHz would be a major advance, but the
Reg provides no info on where they got that
number, or if they just made it up.

[nickcarraway]

Article on the same topic here:Intel Eyes Future Transistor

[nevergiveup]

Yawwwwwwn!
I was making III-V transistors with indium and phosphorus (InP = Indium Phosphide) back in 1973. Indium antimonide ain't that much different.

In theory, they are much much better than silicon BUT they're hard and expensive to make.

Twenty years afterward, I bumped into a guy saying he was developing an InP transistor and had almost solved a major problem. I simply told him to go read my thesis.
The more things change, the more they stay the same.

Gallium Asenide is somewhat better to use (and sell) but III-V devices are definitely specialty devices where $ don't matter.

I'll believe this new IBM announcement when I can buy it in 2015.

[DallasMike]

...indium (In) and antimony (Sb).

Indium? So now we're outsourcing raw materials?

[Marine_Uncle]

Thought you may be interested.

[ikka]

Nope, they are Native American Indiums .

[Ernest_at_the_Beach]

Thanks...not sure how the masses are going to make us of all the compute power that is coming.

[CompSciGuy]

Not sure about the feasibility of the cost of the production process, but wouldn't supply and demand reduce the cost (after it was in mass production)? Or would it still be expensive even then? Rather curious to know the answer.

Cheers,
CSG

[SW6906]

BTTT for Moore's Law!

[SunkenCiv]

Intel Announces Chip Technology Breakthrough Using New Materials
YAHOOOoooooooo | Wednesday December 7, 11:00 am ET
Posted on 12/07/2005 8:21:36 AM PST by BenLurkin
http://www.freerepublic.com/focus/f-news/1535698/posts

[SunkenCiv]

Oops, sorry, I clicked before I took your name out of the "To" box in the previous post.