Intel: Metal in Future Chips = Less Leakage

securitas writes "Intel is contemplating using metal instead of silicon in future chips for the 'transistor gate, which controls whether a transistor is on or off' and the 'dielectric, an insulating layer below the gate,' which are respectively made of silicon atoms and silicon dioxide. 'Millions of minuscule switches that make up silicon chips leak electricity when they're supposed to be shut off. To compensate, engineers have increased the current, driving up power consumption, decreasing battery life for portable devices and generating more heat.' AMD has also experimented with metal instead of silicon. By moving to metal AMD and Intel expect to reduce electricity leakage. More from AP via SeattlePI and the Miami Herald." Update: 11/05 15:25 GMT by T : Read on below for some information from Intel on why this is a good thing.

gManZboy writes "Following up on the Intel news that about using metal in chips -- here's an explanation from Shekhar Borkar (Intel Research Fellow) about why heat, power, and sub-threshold leakage, not transistor size, are the real challenges to Moore's law. Apparently, in order to make chips much faster, we're going to have to pump more electricity in then anything else in our houses -- and they'll soon be as hot as a nuclear reactor -- no, really."

Metal Implants?

[telstar]

Man, and here I thought silicon felt weird.

Re:Which metal?

[MikeD83]

In the AMD article the use of Nickel is mentioned.

Metal dielectric!?

[CaptainAlbert]

I have no trouble understanding a switch from poly to metal for gate connections... but a metal dielectric? That seems to run counter to common sense. The dielectric is, by definition, required to be an insulator, whereas metals, also by definition, conduct electricity rather well. What is this magic substance?

I love this site sometimes - where else can you post completely clueless questions and be virtually guaranteed to get an intelligent response from at least two people with PhDs in semiconductor physics? :-)

Re:Metal dielectric!?

[inl101]

I'm about 6 months away from my PhD in semiconductor physics.

They mean metal oxides. Leading candidates are Halfnia and Zirconia. These are "High-K dielectrics".

Using both reduces the Effective Oxide Thickness (EOT) of the gate dielectric. For the same thickness material, high-k dielectrics look like a thinner amount of silicon dioxide. Metal gates eliminate depletion effects in the gate (poly-depletion), which also makes the oxide look thinner.

With lower EOT, the gate has better control of the channel, so leakage goes down.

Re:Metal dielectric!?

[Cougar1]

Tantalum oxide is a good high-k dielectric, but it is not thermodynamically stable in contact with Si. As a result, Ta2O5 reacts with Si during the high temperature (>900 C) anneals necessary to activate the Si dopants. These unfavorable reactions ruin the devices and as a result Ta2O5 has largely been abandoned as a potential dielectric in Si transistors. Ta2O5 is used for capacitors in DRAM memory devices.

Re:Copper?

[msgmonkey]

You are thinking of the Copper traces instead of Aluminium, the transistors remained Silicon. Here they are talking about metal transistors.

Time for change...

[stm2]

to MetalValley!

Now, instead of "experiment in silico", it would be "in metal" (??) or "in Fe|Au|Cu" :)

What about...

[the_bahua]

...diamonds?

I thought that the manufacture of diamonds was set, and only needed to step up its production. Gemesis has been making, for less than $100, gems that would be worth hundreds of thousands if naturally mined.

The most promising thing about these diamonds is that, being cheap, they open the door for cpu cooling. Diamonds are tolerant of exponentially higher temperatures than silicon, so why aren't we hearing about intel, amd, motorola, ibm, TI, and sgi taking advantage of this new technology.

Metal? What about metal is unprecedented? What about it has kept us from using it before? Diamonds are the future, not metal.

Re:What about...

[October_30th]

Intense lobbying, FUD and outright threats from the diamond industry have managed to suppress any large scale production of perfect diamonds (you can't do chips using crude industrial grade diamonds).

You see, diamonds are seriously overpriced luxury items. Although it is possible to manufacture cheap diamonds that are indistinguishable from the natural ones, it has never been done. Why? It would ruin the entire business model of De Beers & co. which is based on artificial scarcity. That's why they'd fight such projects to the bitter end.

Re:What about...

[l3prador]

Actually, it's currently being done by Apollo Diamonds and Gemesis, which was mentioned above. De Beers is fighting them as hard as they can, but even if they convince the public that manmade diamonds aren't worth anything as jewelry, they will still be able to use them for computing. However, production is not quite ready for large-scale chip manufacturing, which is why Intel and others have not yet turned to diamonds.

From Intel's site...

[sczimme]

The history of Moore's Law.

Or if you are interested in Moore's original paper, you can find it here.

Clueless, thy name is reporter

[overshoot]

To clarify: the idea is to use a gate dielectric which has a higher dielectric constant than silicon dioxide. Most of the candidates are metallic oxides, nitrides, etc. That allows the transistors to have thicker gates for the same gate capacitance (which is how MOS transistors work).

The chemistry of the non-silica gate dielectric requires that the gate itself be non-silicon, and metals are better conductors anyway. (For larger transistors, we're already running into trouble from the distributed resistance of the gates.)

Hope that helps.

Hadn't IBM already done this

[adzoox]

I was aware that IBM's copper on silicon insulator already acheived less leakage and less power consumption, also increasing power (per Mhz) in each cycle. G3's (for Apple Computers have had this for over 2 years) and G5's also have it.

Interesting how IBM has discovered that moving to metal for processors and away from metal for hard drives. (Newest Hitachi/IBM notebook drives use Pixie dust which is actually glass. The platters in these hard drives are also ferro impregnated glass platters)

Re:say what?

[stevel]

Why is VLIW not more popular? Because compiler technology isn't yet good enough and current VLIW designs have restrictions that get in the way of the best performance.

Over the years, there have been many attempts to use techniques such as VLIW, which sound great on paper, but don't do well in practice. What have worked the best, at least through the 90s, are architectures that do a lot of simple things fast.

You can make VLIW fast, Intel has managed that, but at great cost in both silicon and software.

Be careful when making generalizations about a processor line such as the P4 - there have been quite a few P4 generations, each better than the last. Latencies have gone down.

I think that parallelism (eg. HyperThreading, multicore, etc.) is where the real-world performance gains will come from. Single-threaded benchmarks don't accurately reflect realistic workloads.

Re:Copper?

[DarthTaco]

You are thinking of the Copper traces instead of Aluminium, the transistors remained Silicon. Here they are talking about metal transistors.

Not true at all. The copper in IBM's process is for interconnects, not traces. I'm not sure what metal they use for the traces, but it's probably aluminum and definitely not copper. The connection between layers (interconnect) are copper plugs.

The metal intel is talking about is strictly for the gate terminal connection of the transistor. The transistor is still doped silicon or gallium arsenide or whatever semiconductor they are using.

Re:Which metal?

[Cougar1]

I dont see any mention of the type of metal that would be most suitable. I'm sure all metals are n't created equal.

Actually, two types of metal are probably needed. One for nmos transistors and another for pmos transistors. Nmos and pmos transistors have different threshold voltages (the voltage at which the device turns on), but ideally you would like both types of transistors to switch at the same voltage. The threshold voltage of a device can be shifted by modifying the "workfunction" of the gate metal. The workfunction is the energy required to remove an electron from the metal surface.

One reason polysilicon gates are used in conventional CMOS is that the workfunction of polysilicon can be modified by changing the level of doping and the type of dopant material (usually B, P or As). Thus, polysilicon gates can be used for both nmos and pmos transistors and by varying the doping, both types of devices can have the same threshold voltage.

Shifting the workfunctions of metals, using dopants is not so straightforward. As a result it will probably be necessary to use two different metals having different workfunctions for nmos and pmos transistors. Further complicating matters is the fact that the gate metal can interact with the dielectric material, modifying the effective workfunction and thus the threshold voltage. So, while the isolated metal may have the necessary workfunction, the workfunction may shift when the metal is part of a device. Thus, a lot of testing and experimentation is needed to find a metal that has the proper workfunction after it has been put into a device.