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主题:【评论】摩尔定律的尽头! -- Highway

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家园 【评论】摩尔定律的尽头!

英特尔的创始人摩尔(Gordon Moore )在1965年预言,芯片工业每两年就可以将晶体管数量翻一番。事实上,芯片工业每18个月就将晶体管数量翻一番。其主要技术就是不断的缩小晶体管的体积。但是晶体管的体积终究有个极限。英特尔的科学家们预测在2018年左右,当晶体管小到16纳米时,摩尔定律将会走到尽头。

点看全图

外链图片需谨慎,可能会被源头改

那怎么办呢,请看下文。。。

Moore's Law, as chip manufacturers generally refer to it today, is coming to an end, according to a recent research paper.

Granted, that end likely won't come for about two decades, but Intel researchers have recently published a paper theorizing that chipmakers will hit a wall when it comes to shrinking the size of transistors, one of the chief methods for making chips that are smaller, more powerful and cheaper than their predecessors.

Manufacturers will be able to produce chips on the 16-nanometer manufacturing process, expected by conservative estimates to arrive in 2018, and maybe one or two manufacturing processes after that, but that's it.

News.context

"This looks like a fundamental limit," said Paolo Gargini, director of technology strategy at Intel and an Intel fellow. The paper, titled "Limits to Binary Logic Switch Scaling--A Gedanken Model," was written by four authors and was published in the Proceedings of the IEEE (Institute of Electrical and Electronics Engineers) in November.

Although it's not unusual for researchers to theorize about the end of transistor scaling, it's an unusual statement for researchers from Intel, and it underscores the difficulties chip designers currently face. The size, energy consumption and performance requirements of today's computers are forcing semiconductor makers to completely rethink how they design their products and are prompting many to pool design with research and development.

Resolving these issues is a major goal for the entire industry. Under Moore's Law, chipmakers can double the number of transistors on a given chip every two years, an exponential growth pattern that has allowed computers to get both cheaper and more powerful at the same time.

Mostly, the trick has been accomplished through shrinking transistors. With shrinkage tapped out, manufacturers will have to find other methods to keep the cycle going.

These issues will likely be widely discussed this week, when the International Technology Roadmap for Semiconductors is unveiled in Taiwan. The ITRS, which is comprised of several organizations, including the Semiconductor Industry Association, outlines the challenges and rough timetable for the industry for 15 years. A new version of the plan will be released in Taiwan on Dec. 2.

Still, Gargini said, researchers are exploring a variety of ideas, such as more efficient use of electrons or simply making bigger chips, to surpass any looming barriers. Other researchers likely will dispute these conclusions.

"We cannot let physics beat us," he said, laughing.

The distinguished circuit

The problem chipmakers face comes down to distinction and control. Transistors are essentially microscopic on/off switches that consist of a source (where electrons come from), a drain (where they go) and a gate that controls the flow of electrons through a channel that connects the source and the drain.

When current flows from the source to the drain, a computer reads this as a "1." When current is not flowing, the transistor is read as a "0." Millions of these actions together produce the data inside PCs. Strict control of the gate and channel region, therefore, are necessary to produce reliable results.

When the length of the gate gets below 5 nanometers, however, tunneling will begin to occur. Electrons will simply pass through the channel on their own, because the source and the drain will be extremely close. (A nanometer is a billionth of a meter.)

Gargini likens the phenomenon to a waterfall in the middle of a trail. If a person can't see through it, they will take a detour around it. If it is only a thin veil of mist, people will push through.

"Where you have a barrier, the electrons penetrate a certain distance," he said. "Once the two regions are close enough, because of tunneling, the charge will go from A to B, even when a voltage is not applied to the gate."

At this point, a transistor becomes unreliable as a source of basic data, because the probability of spontaneous transmission is about 50 percent. In other words, Heisenberg's uncertainty principle is in action, because the location of the electrons can't be accurately predicted.

In chips made on a 16-nanometer technology process, the transistor gate will be about 5 nanometers long.

"At 5-nanometer gate dimension, I would have to agree with them," said Craig Sander, vice president of process technology development for AMD. "I think we will find applications that don't require that we stay on such an aggressive roadmap."

When these chips will start to be produced is a matter of debate. On paper, new manufacturing processes come out every two years. Chips made on the 90-nanometer process, which contain gate lengths of about 37 nanometers, are just starting to be produced. On a two-year cycle, this would mean that 16-nanometer chips would appear in 2013 with the barriers preventing new, smaller chips in 2015.

Manufacturers, however, have had to delay the introduction of new processes recently. Using a three-year calendar, 5-nanometer chips won't hit until 2018 or 2019, putting a barrier generation at about 2021. The ITRS timetable will provide more details about the different manufacturing technologies for a given year.

The tunneling effects, Gargini said, will occur regardless of the chemistry of the transistor materials. Several researchers over the years have predicted the end of Moore's Law but made the mistake of extrapolating on the basis of existing materials.

Designers, however, continually change the materials and structures inside semiconductors. Intel and rival Advanced Micro Devices, for instance, are looking at replacing silicon transistor gates with metallic gates so that chips can be mass-produced with 45-nanometer manufacturing--expected between 2007 and 2009. Gates on this process will be about 18 nanometers, according to the ITRS timetable.

The concept behind the Intel researchers' paper was, "why don't we do something based entirely on fundamental principles?" Gargini said. "The beauty of our paper is that it is independent of materials."

Theoretically, chip designers could squeeze the size a bit more. "You could probably go to 4" nanometers, he said, but that would require increasing the energy needed to run the chip to make the barrier less susceptible to tunneling.

Energy a burning problem

Energy consumption, however, is already a major problem for chip designers. Not only is it increasingly difficult to provide energy to a chip, the ambient power-driven heat can cause major malfunctions.

"Scaling for binary switches, packed to maximum density, is ultimately limited by the system capability to remove heat," the paper stated. "Simultaneous gains in packing density and speed of operation will eventually be replaced by a trade-off between packing density and speed in order to satisfy heat removal constraints."

Like other researchers, Gargini sees no easy solution to energy consumption. Active cooling systems can reduce the internal temperature of computers but require independent energy sources, which create about as much heat as they remove. As a result, even if transistors with gate lengths that measure 3 nanometers could be made, a chip that contained them would hypothetically overheat itself.

"From a total energy point of view, you are not fooling mother nature," Gargini said.

Even if the energy consumption and tunneling problems can be solved, transistors will hit a limit when the gate reaches 1.5 nanometers in length, he said. The number comes from a calculation researchers made when examining what is the smallest well from which an electron could be extracted, Gargini said.

Unlike a conventional transistor, where the source, channel and drain sit in a horizontal line, a transistor at the 1.5-nanometer level might be vertically structured. On the shrinkage rules, transistors with this sort of gate would occur about four to six years after the transistors with 5-nanometer gates, or 2017 to 2025.

One extremely theoretical potential idea is to reuse electrons. In current architectures, electrons travel from a source to a drain and then are destroyed. With recycling, "you simply transfer the electron to something else," Gargini said. "You can make a lot of calculations without destroying the electrons."

Carbon nanotubes and silicon nanowires are another alternative. Transistors made of these materials are of comparable sizes. Carbon nanotubes have a diameter of 1 to 2 nanometers, but they are stretched lengthwise between a source and drain in experimental transistors. In the end, performance could go up--and energy consumption could decline--but size will stay about the same.

"Exotic structures, such as carbon nanotubes, may find their way into CMOS (Complementary Metal Oxide Semiconductor) applications, not so much driven by acceleration of the scaling cadence, but more likely to enhance the performance of CMOS devices, or perhaps to simplify fabrication," the paper stated. "Even if entirely different electron transport devices are invented for digital logic, their scaling for density and performance may not go much beyond the ultimate limits obtainable with CMOS technology, due primarily to limits on heat removal capacity."

Another alternative is to make the chips bigger, add transistors by adding more real estate or building 3D chips, in which layers of transistors form a high rise. These solutions have been conjectured by Intel co-founder Gordon Moore and Stanford professor Tom Lee, among others.

家园 哪里有BOTTLENECK,哪里就有机会。
家园 追随摩尔定律,无异饮鸩止渴

其实摩尔定律对IC工业地误导很大,仿佛管子多了,产品就好了,因此竞相采用新工艺,往往对现有技术地潜能没有完全开发,就换到新工艺,因为这个办法简单。

但是这是透支将来地技术,后代们怎么办?全新地工艺发明出来又谈何容易。譬如纳米,数来数去,真正工业化的就大陆生产了纳米冰箱,纳米洗衣机,袜子鞋垫之类。

家园 什么才是真正的高科技?

小刀一己之陋见 还望各方有识之士倡言一议

1

MOORES LAW 只是一个预言:

芯片工业每两年就可以将晶体管数量翻一番。

而且价格会按照这个比例下降.

这个预言三十八年以来还蛮准的

不得不佩服这位老先生的高瞻远瞩

要知道三十八年前可没有SUPER COMPUTER能做非武器设计方面的MODELLING

我想因为如此,所以北美几乎每个学校都引用这个预言告诫新入门的 EE 和 PHYSICS 学生

(小刀窃以为当年GORDAN MOORE只怕是酒后语不惊人死不休 没想到真个让他碰上了)

不过小刀对这位老先生是极为佩服的

GORDON MOORE一辈子大都是和员工一起坐在CUBICLE里面

比起现在那些个为钱丧心病狂的CEO可好了太多去了

可能是因为都是白手起家吧,老一辈的CEO比现在的一些暴发富的人品都好太多了

2

所以小刀窃以为 MOORES LAW 并没有误导SEMICONDUCTOR INDUSTRY

这只是这行工业的 NATURE 罢了

BISECTION说道"往往对现有技术地潜能没有完全开发,就换到新工艺,因为这个办法简单"

小刀窃以为只说对了一小半

换到新工艺可不简单

不在其位 不知其苦啊 (苦笑)

小刀一直以为现在所谓的HIGH TECH有一个很威险的趋势:

那就是大家都在盲目的追求CPU SPEED

说到底,是INTEL在领导着大家在玩另类的军备竞赛.

由 MARKETING 来领导 DESIGN 真是盲人指路.

更糟的是如今许多CEO都是做MARKETING 或 SALES 出身的,不太懂科学

和他们在一起开会,那个累那个气啊, (苦笑)

一直以来 INTEL只用CPU的CLOCK SPEED做卖点来打击AMD和APPLE

现在INTEL 自己推出了INTEL CENTRINO (迅腾晶片) 它的CLOCK SPEED比一般的INTEL P4要慢,但实际的处理速度并不比P4差,所以INTEL是以己之手掴己之首啊.

3

刚刚还和几位朋友(台湾来的台独的哦)谈到:

这几十年来人类科技的进步可以说超越了以前几个世纪的

但是人类的道德标准确没有同速的长进?

那么我们要问的是:

什么样的高科技才真正值得我们去追求?

什么才是可以为人类千秋万代造福的大计?

难道我们披心沥血做出来的产品只是让 GAMES 跑的更快?让人类更堕落?

4

纳米工业可不是说着玩的,也没有那么简单.

大陆以外没有什么纳米工业是有其原因的,太复杂了.

小刀的一位授业恩师十几年来就是做"NANOTUBE"研究的. 小刀以前做过他的ASSISTANT,吃不了安贫乐业的苦而逃了出来.

小刀当年得授业恩师悉心教导,如今却和误世奸商同流合污 惭愧哪.

何乍麻院士曾写过一篇批评一轰而上的纳米工业的文章

深得吾心

想想60年的土法炼钢吧.

5

酒兄说的不错,哪里有BOTTLENECK 哪里往往就有突破

几十年来,一直有人说SEMICONDUCTOR的BARRIER会在0.5um

突破了0.5,又有人说会在0.25um 然后是 0.13um

不过我想现在大家心里都没底

不是一件坏事 可也不是很好

不过小刀看来 这样玩起来才刺激精彩

6

再讲一道往事 小刀的一位至交供职RAYTHEON (没错,就是那家造爱国者导弹的公司,这位老兄玩导弹胡天胡地的故事可有趣了,有机会再聊)

他曾告诉我:几十年前GORDON MOORE 等人曾想和RAYTHEON合作造CPU,结果被一位军队出身的老总一口回绝,

据说话还说的蛮损.

现在再看这两家公司

所以以外行领导内行的结局往往如此

家园 老兄好像传说中的“小李飞刀”嘛!看来小宋大侠是名归实致!

在下佩服的紧!

家园 那位老先生也可以称得上先知先觉了

妙人一个

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