半導(dǎo)體特征尺寸正在向22/15nm的等級(jí)不斷縮小,傳統(tǒng)的平面型晶體管還能滿足要求嗎?有關(guān)這個(gè)問題,業(yè)界已經(jīng)討論了很久。現(xiàn)在,決定半導(dǎo)體制造技術(shù)發(fā)展方向的歷史拐點(diǎn)即將到來,盡管IBM和Intel兩大陣營在發(fā)展方式上會(huì)有各自不同的風(fēng)格和路線,但雙方均已表態(tài)稱在15nm級(jí)別制程啟用全耗盡型晶體管(FD:Fully Depleted)技術(shù)幾乎已成定局,同時(shí)他們也都已經(jīng)在認(rèn)真考慮下一步要不要將垂直型晶體管制造技術(shù)如三門晶體管,finFET等投入實(shí)用。
據(jù)Intel的制程技術(shù)經(jīng)理Mark Bohr表示,Intel 對(duì)部分耗盡型(PD  artliy Depleted)CMOS技術(shù)能否繼續(xù)沿用到15nm制程節(jié)點(diǎn)感到“非常悲觀”。但他同時(shí)表示,雖然只有SOI技術(shù)才可以在保留傳統(tǒng)平面晶體管結(jié)構(gòu)的條件下應(yīng)用FD技術(shù);但是體硅制程也并非無可救藥,采用三門或者FinFET等立體晶體管結(jié)構(gòu)技術(shù),便可以在體硅或者SOI上滿足關(guān)鍵尺寸進(jìn)一步縮小的需求,一樣也可以制造出FD MOSFET。
Gartner的分析師Dean Freeman則表示,目前半導(dǎo)體業(yè)界所面臨的情況與1980年代非常類似,當(dāng)時(shí)業(yè)界為了擺脫面臨的發(fā)展瓶頸,開始逐步采用CMOS技術(shù)來制造內(nèi)存和邏輯芯片,從而開創(chuàng)了半導(dǎo)體業(yè)界的新紀(jì)元。 柵極寬度不斷減小所帶來的負(fù)面效應(yīng)越來越明顯。首先,為了消除短通道效應(yīng),人們不得不向溝道中摻雜磷,硼等雜質(zhì)元素,這便導(dǎo)致管子門限電壓Vt的上升,同時(shí)還降低了溝道中電子流動(dòng)的速度,造成管子速度的下降。而且用來向溝道中摻雜雜質(zhì)的離子注入工藝也存在很難控制的問題,很容易造成管子門限電壓過大等不良結(jié)果。
其次,傳統(tǒng)的SiGe PMOS硅應(yīng)變技術(shù)也開始面臨瓶頸,在32nm制程節(jié)點(diǎn)中,漏源兩極中摻雜的鍺元素含量已經(jīng)占到了40%左右,很難再為溝道原子提供更高級(jí)別的應(yīng)變. 其三,柵極氧化物的厚度方面也將出現(xiàn)發(fā)展瓶頸問題.IBM研發(fā)中心的高管Bruce Doris表示,柵極氧化物厚度減薄的速度已經(jīng)跟不上柵極寬度縮小的步伐. 其它一些平面型晶體管所面臨的問題也將越來越難解決.工作電壓的不斷升高,使芯片的功耗控制變得越來越困難;而且關(guān)鍵尺寸的縮小還會(huì)導(dǎo)致漏/源極電阻的不斷增大. 那么業(yè)界有什么策略來應(yīng)對(duì)這些挑戰(zhàn)呢? Intel的戰(zhàn)略:22nm仍采用傳統(tǒng)技術(shù),15nm可能轉(zhuǎn)向三門結(jié)構(gòu) 據(jù)Intel表示,在下一代22nm制程產(chǎn)品中,他們?nèi)詫⒗^續(xù)采用傳統(tǒng)基于體硅的平面型晶體管結(jié)構(gòu)(此前曾有傳言稱 Intel會(huì)在22nm制程中轉(zhuǎn)向立體結(jié)構(gòu)的三門晶體管技術(shù)),他們計(jì)劃于2011年底正式推出22nm制程技術(shù)。而在今年的9月份,Intel已經(jīng)展示過一款采用22nm制程技術(shù)制造的SRAM芯片,這種芯片的存儲(chǔ)密度為364Mb,內(nèi)含29億個(gè)晶體管,并且采用了Intel第三代gate-last HKMG制程技術(shù),門極絕緣層和金屬柵極的主要部分在制造工序的最后幾個(gè)工步制造成型,避開前面的高溫退火工步(45/32nm中使用的前代技術(shù)則只有金屬柵極才在最后幾個(gè)工步制造成型)。 至于15nm制程節(jié)點(diǎn),Bohr表示,Intel目前正在考慮在15nm制程節(jié)點(diǎn)上要采用哪些新的制程技術(shù)以滿足要求,他認(rèn)為:“全耗盡技術(shù)對(duì)降低芯片的功耗非常有效。”不過 Intel目前也在考慮除此之外的多種可行性方案,比如是轉(zhuǎn)向三門晶體管技術(shù)(三門技術(shù)其實(shí)與IBM的雙門finFET同屬finFET型晶體管,但由于對(duì)手將其雙門技術(shù)命名為finFET,因此Intel便根據(jù)自己的finFET技術(shù)特點(diǎn)將其命名為三門技術(shù)),或者是轉(zhuǎn)向全耗盡+平面型晶體管技術(shù)等等。據(jù)Bohr表示,Intel會(huì)在六個(gè)月之內(nèi)就15nm制程節(jié)點(diǎn)將采用哪一種新技術(shù)做出決定。 此前據(jù)Intel前技術(shù)經(jīng)理Scott Thompson預(yù)計(jì),Intel最終會(huì)選擇采用三門結(jié)構(gòu)晶體管制程,而其它的廠商則會(huì)因?yàn)镕inFET結(jié)構(gòu)的制程工藝復(fù)雜性而對(duì)FinFET望而卻步。Scott Thompson現(xiàn)在的職位是在佛羅里達(dá)大學(xué)任教。 按Intel的脾氣,他們一向?qū)OI工藝保持抗拒的態(tài)度。不過Bohr表示:“我們要找的是一種性價(jià)比最高的方案,不管是SOI或者其它的什么技術(shù),只要某種技術(shù)能夠帶來額外的性能提升或較低的功耗,那么我們就會(huì)采用這些技術(shù)。” IBM陣營的戰(zhàn)略:22nm有可能轉(zhuǎn)向FD-ETSOI,15nm可能啟用finFET結(jié)構(gòu) IBM陣營方面,與Intel不同,盡管有可能后延到15nm制程節(jié)點(diǎn)時(shí)間段,但I(xiàn)BM公司已經(jīng)開始考慮要在22nm制程節(jié)點(diǎn)便開始使用FD-SOI技術(shù)。IBM公司12月份曾經(jīng)展示了一種基于ETSOI(extremely thin SOI:超薄SOI)的FD-ETSOI工藝。這種工藝仍然基于傳統(tǒng)的平面型晶體管結(jié)構(gòu),不過這種工藝的SOI層厚度則非常薄,這樣便可以采用全耗盡工藝,能夠顯著減小短通道效應(yīng)(SCE)的影響。
ETSOI技術(shù)能將SOI層的厚度縮小到極低的水平,使用這種技術(shù)之后,22nm制程中的SOI層的厚度僅有6.3nm,而傳統(tǒng)的SOI層厚度通常在 20nm以上,發(fā)展到15nm制程,SOI層的厚度還可以進(jìn)一步被縮小到5nm左右。據(jù)IBM表示,盡管由Soitec公司提供,能用于制造ETSOI產(chǎn)品的SOI晶圓數(shù)量仍十分有限,但他們已經(jīng)可以把這種SOI層的厚度誤差控制在±5 ?左右. 不過ETSOI技術(shù)也有其難點(diǎn),由于SOI層的厚度極薄,因此很容易受到損壞。而且為了避免對(duì)SOI層造成損壞,在制造漏/源極時(shí)不能采用傳統(tǒng)破壞性較強(qiáng)的離子注入技術(shù),必須采用就地?fù)诫s技術(shù)(in-situ doping)。“我們采用的是不會(huì)損害ETSOI層的就地?fù)诫s技術(shù)。我們首先生成柵極隔離層,然后在漏源區(qū)用外延技術(shù)沉積生長出漏/源極,形成外延層(圖中的epi)并在漏/源極的生長過程中同時(shí)就地?fù)诫s所需的雜質(zhì)元素,然后我們會(huì)對(duì)晶體管進(jìn)行加熱處理,令漏源極中的摻雜原子向溝道方向擴(kuò)散,形成擴(kuò)散層(圖中的ext)。而加熱處理過程中我們使用的尖峰退火技術(shù)(spike anneal )則不會(huì)對(duì)ETSOI層的結(jié)構(gòu)造成不必要的損害。” 隸屬IBM技術(shù)同盟的GobalFoundries的技術(shù)開發(fā)經(jīng)理John Pellerin也表示這種FD-ETSOI技術(shù)很快便會(huì)付諸實(shí)用,不過他表示:“但是我們現(xiàn)在很難說具體什么時(shí)候會(huì)轉(zhuǎn)向這種技術(shù)。”Pellerin表示,F(xiàn)D-SOI技術(shù)從應(yīng)用結(jié)構(gòu)上看與現(xiàn)有的PD-SOI技術(shù)非常相近,“我們只需要把SOI層的厚度變薄,并想辦法解決ETSOI帶來的一些問題即可,其它的部分則和傳統(tǒng)的制造工藝基本相同。”當(dāng)然ETSOI技術(shù)仍有許多其他的問題需要解決,比如如何減小器件的寄生電阻等等。 IBM的下一步:finFET 另據(jù)Pellerin表示,在ETSOI技術(shù)發(fā)展的下一步很可能會(huì)開始啟用finFET立體型晶體管結(jié)構(gòu),兩者的關(guān)系就像過去我們從部分摻雜型SOI(PD-SOI)技術(shù)過渡到FD-SOI那樣。“我看不出來ETSOI和finFET兩種技術(shù)之間存在什么矛盾之處,而且采用平面型結(jié)構(gòu)ETSOI技術(shù)所能達(dá)到的晶體管密度總會(huì)出現(xiàn)發(fā)展瓶頸,而finFET則可以解決這種問題。” 2009年,IBM公司增加了用于實(shí)驗(yàn)finFET效能的晶圓樣片數(shù)量,據(jù)他們表示,finFET技術(shù)所帶來的性能提升“令人非常滿意。”不過 finFET與平面型晶體管之間各有優(yōu)劣。“平面型晶體管結(jié)構(gòu)并不需要對(duì)傳統(tǒng)的工藝進(jìn)行太多改進(jìn),過去30年來人們所使用的很多技術(shù)都可以應(yīng)用在平面型結(jié)構(gòu)的ETSOI里,而要進(jìn)一步升級(jí)為finFET結(jié)構(gòu),所需要的制造工藝則復(fù)雜得多,這種技術(shù)對(duì)光刻和蝕刻技術(shù)提出了很高的要求。” ETSOI輔助技術(shù):SiC硅應(yīng)變技術(shù) 在22nm節(jié)點(diǎn),看起來至少1家以上的大型廠商會(huì)采用向NMOS管的漏源區(qū)摻雜碳原子的方法來為溝道施加拉伸應(yīng)力,以形成應(yīng)變硅。IBM在描述自己的 FD-ETSOI工藝時(shí)曾經(jīng)提到,他們會(huì)在沉積NMOS管的漏源極時(shí)向極內(nèi)摻雜碳雜質(zhì)。而且另外一家IBM工藝技術(shù)聯(lián)盟的成員Applied Materials公司也分別在去年的IEDM和今年的Semicon會(huì)展上兩次強(qiáng)調(diào)了這種SiC硅應(yīng)變技術(shù)的可行性。 那么外界對(duì)SiC 技術(shù)的評(píng)價(jià)如何呢?據(jù)GlobalFoundries公司的Pellerin表示:“我們正在關(guān)注SiC硅應(yīng)變技術(shù),并且正在考慮在我們的22nm及更高級(jí)別制程中使用這項(xiàng)技術(shù)。”在目前的工藝尺寸條件情況下,要想很好地控制漏源區(qū)的離子注入過程將是一項(xiàng)非常復(fù)雜的任務(wù),而在IBM的FD-ETSOI工藝中,NMOS中使用的SiC硅應(yīng)變技術(shù)則與PMOS中的SiGe硅應(yīng)變技術(shù)一樣是采用外延沉積實(shí)現(xiàn)的,不必再為如何控制離子注入而擔(dān)憂。他并表示:“如何在NMOS管中應(yīng)用硅應(yīng)變技術(shù)將是另外一個(gè)改善晶體管性能的關(guān)鍵技術(shù)。” 相比之下,Intel的Bohr則完全改變了他對(duì)SiC硅應(yīng)變技術(shù)的態(tài)度,他過去曾經(jīng)表示 Intel更傾向于使用SiC硅應(yīng)變技術(shù),不過最近他在IEDM2009會(huì)議中接受采訪時(shí)則表示他不愿意就Intel在SiC硅應(yīng)變技術(shù)方面取得的進(jìn)展發(fā)表任何評(píng)論。而會(huì)上代表Intel做有關(guān)Intel 32nm制程技術(shù)演講的Paul Packan則在演講后回答記者提問的環(huán)節(jié)沒有理會(huì)一位記者提出的有關(guān)SiC硅應(yīng)變技術(shù)在32nm制程N(yùn)MOS結(jié)構(gòu)中應(yīng)用狀況的問題。 小結(jié):Intel與IBM:你走你的陽光道,我過我的獨(dú)木橋 Gartner 的分析師Freeman表示,他認(rèn)為Intel和AMD會(huì)繼續(xù)走自己的老路,Intel不太可能會(huì)使用SOI技術(shù),而IBM則會(huì)繼續(xù)將SOI發(fā)揚(yáng)光大。他認(rèn)為Intel如果采用三門晶體管技術(shù),“便可以繞開SOI,因此Intel未必會(huì)轉(zhuǎn)向SOI。”他并表示:“Intel會(huì)盡可能地延長體硅制程的壽命,而IBM則會(huì)盡快轉(zhuǎn)向全耗盡型SOI技術(shù)。”他還認(rèn)為將來Soitec和信越化學(xué)公司(SEH, Tokyo)將具備向IBM提供符合對(duì)方需要的ETSOI晶圓的能力(目前IBM需要在廠內(nèi)對(duì)ETSOI硅層進(jìn)行處理)。 其它關(guān)鍵技術(shù):
除了以上所述的即將投入使用的技術(shù)之外,用于制造場(chǎng)效應(yīng)管溝道的半導(dǎo)體材料下一步也有可能會(huì)發(fā)生變化。在去年的IEDM會(huì)議上,斯坦福大學(xué)的教授 Krishna Saraswat曾表示,當(dāng)溝道寬度降至10nm左右時(shí),必須采用新材料來制造溝道。據(jù)他估計(jì),業(yè)界將首先開發(fā)出NMOS管使用III-V族元素構(gòu)建溝道,PMOS管使用鍺元素構(gòu)建溝道的技術(shù),然后再向PMOS/NMOS統(tǒng)一采用III- V族元素制造溝道的方向發(fā)展。轉(zhuǎn)向使用III-V族元素將大大減小器件的工作電壓和管子的能耗,可將工作電壓減小至0.5V。不久之前,Intel便介紹了他們?cè)谑褂眠@種技術(shù)制造的QWFET場(chǎng)效應(yīng)管方面取得的新進(jìn)展,當(dāng)時(shí)他們向這種晶體管結(jié)構(gòu)中引入了High-K柵極氧化物層。 除此之外,IBM則在TSV硅通孔互連技術(shù)和3D堆疊封裝技術(shù)方面取得了較大的進(jìn)展。 CNBeta編譯 原文:semiconductor |
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CMOS Transitions to 22 and 15 nm Scaling beyond the 22 nm node is likely to require fully depleted CMOS, either on SOI or bulk wafers. TSV 3-D interconnects and SiC stressors also appear likely to be implemented, while the jury is still out on when vertical finFETs and III-V devices will be widely implemented. David Lammers, News Editor -- Semiconductor International, 1/1/2010 Technologists have long debated how far plain-vanilla planar CMOS transistors on bulk silicon wafers could be scaled. Now, the transition to new paradigms appears to be underway, with fully depleted CMOS almost definitely on the 15 nm roadmaps at IBM and Intel, with some form of vertical transistors being seriously considered as well. Mark Bohr, Intel's director of process architecture and integration, said he and his Intel colleagues are "pretty pessimistic that partially depleted (PD) CMOS will extend to the 15 nm node." A planar, fully depleted (FD) technology could only be constructed on a silicon-on-insulator (SOI) substrate, Bohr said, but a tri-gate or finFET device could be created on either bulk or SOI wafers. Gartner analyst Dean Freeman likens the current period to the early to mid-1980s, when first memory and then logic transitioned to CMOS. "The NPN transistor gave the CPU vendors a new lease on life. I think we are at a point like that again. But the question is out there: How do we keep innovating?"
1. Drive currents have been slowed by higher threshold voltages and slowed gate length scaling. (Source: Intel, 2009 IEDM) Changes — whatever they may be — are coming because for the last generation or two, scaling the gate length (Lg) has resulted in reverse scaling (Fig. 1).1 To avoid short channel effects (SCE), more phosphorus and boron are being doped into the channel, raising threshold voltages and slowing transistors speeds. Random dopant fluctuations (RDF), in which the number of dopants in the channel vary as a function of the halo implantation, can have a large influence on the Vt, hurting performance and cutting overall yield. Strain also faces limits. More germanium can be added to the SiGe stressors — from the ~40% germanium level used at the 32 nm node — but there is less room for the material to create the strain. While IBM, Intel and others are thinning the gate dielectric with high-k materials, the gate dielectric "is not thinning as fast as we need it to in order to make an appreciable improvement in gate length scaling," said Bruce Doris, manager of advanced device integration at IBM's Albany, N.Y., R&D center. Other knobs are getting harder to turn as well. Operating voltages are leveling off, making it more difficult to reduce power consumption. Making the junctions shallower is causing the source/drain resistance to increase. What to do? At 22 nm, Intel will stay on a bulk technology, Bohr said. Intel is on track to introduce its 22 nm MPUs at the end of 2011. The Intel 22 nm test chip (Fig. 2) with SRAM arrays and logic peripheral circuits was introduced in September with a 364 Mb array size and 2.9 billion transistors. It includes a third-generation gate-last high-k/metal gate process that deposits both the dielectric and the metals at the end of the process.
2. Intel's 22 nm test chip has 2.9 billion transistors. (Source: Intel) Thus far, performance gains from Intel's strain techniques — including the PMOS strain added from the replacement gate, or gate last, method of depositing high-k/metal gates — have more than compensated for the speed degradation coming from the deleterious effects of channel doping. Going forward, however, Bohr said "further invention" will be needed, beyond pitch and gate length scaling. Now working on pathfinding technologies for the 15 nm generation, Bohr said, "Fully depleted technologies have inherent low-power advantages." Intel is exploring a range of options, Bohr said, including tri-gate devices and fully depleted planar technologies. Intel has a decision to make in about six months, when it will lock in the process architecture for its 15 nm technology. (Scott Thompson, a former Intel technology manager who now teaches at the University of Florida at Gainesville, believes Intel will adopt a tri-gate structure at some point, while the rest of the industry will shy away from the manufacturing challenges of finFETs.) Historically, Intel has not been positive about SOI for partially depleted, planar CMOS devices. "We look for value," Bohr said. "Whether it is SOI or an extra metal layer, we do it if it gives us extra performance or lower power." John Pellerin, director of technology development for GobalFoundries, also said fully depleted CMOS is coming, though he said it is "difficult to draw discrete lines in the roadmap where such transitions occur." As a foundry that counts Advanced Micro Devices Inc. (AMD, Sunnyvale, Calif.) as its first customer, GlobalFoundries will support AMD and others with an SOI roadmap, while advancing bulk for other customers. Because so many companies are pooling R&D resources at the Fishkill Alliance, Pellerin said, "We do have the benefit of pursuing multiple architectures in parallel. Bulk is the incumbent for many applications, while for some high-performance sectors, PD-SOI is the incumbent. When those are dethroned is difficult to predict. What we do is look at novel architectures while at the same time raising the bar of the incumbents. That makes it more challenging for the newcomers." Partially depleted or conventional bulk transistors "become quite difficult" as scaling proceeds, Pellerin said. "In order to get the short channel characteristics required, certainly fully depleted device architectures — be they vertical devices like finFETs or planar SOI — allow you to take that challenge of channel control out of the equation. That's the enticement: not stuffing a lot of doping in the channel to control the short channel effect." The ability to get a consistent amount of doping in the channel is becoming difficult to manage. "That's where variation gets difficult," Pellerin said, "and where a fully depleted type of architecture starts to look very attractive." IBM, for its flagship MPU process technology, is considering making a move to fully depleted technologies as early as the 22 nm node, though it is more likely to come at 15 nm. Ghavam Shahidi, director of silicon technology at the T.J. Watson Research Center (Yorktown Heights, N.Y.), said IBM is developing fully depleted transistors, using planar structures on extremely thin SOI (ETSOI) wafers.2 ETSOI results in a thin silicon body, which reduces short channel effect (SCE) problems that stem from scaling the extensions to less than the depletion width. "Thin-body devices make the thinning of the extensions simpler, and they reduce the [gate-induced drain leakage] and Vt variations. The undoped body has much lower leakage and dopant variations," Shahidi said. PD-SOI involves learning to deal with the SOI history effect, which affects the Vt level and complicates design somewhat. With FD-SOI, there is no history effect, which makes FD-SOI design much simpler for smaller companies. The ETSOI technology incorporates several process innovations, including in situ doped epitaxial (implant-free) deposition of the source/drain and extension regions, and a faceted raised source/drain architecture, said Kangguo Cheng, lead engineer on the 22 nm device integration team at IBM's Albany R&D center.
3. Extremely thin SOI technology requires a thin silicon layer, and small thickness variations. (Source: IBM) ETSOI requires an extremely thin body, with the critical silicon layer on the SOI wafer in the 6.3 nm range for the 22 nm generation, and even thinner, ~5 nm, for 15 nm devices (Fig. 3). Doris said most of the 300 mm SOI wafers delivered to IBM from Soitec (Bernin, France) have an acceptable silicon thickness variation of ±5 Å, although the shipments from Soitec have been in limited quantities thus far. ETSOI processing must be done carefully beacuse the thin silicon layer can recrystallize. "The silicon is so thin," Cheng said, "once you destroy the top silicon layer there is nothing left to recover." In situ doping, rather than implantation, is required, also to avoid material destruction.3 "We do in situ doping, which is non-destructive. We form the spacer, and need to leave the S/D epitaxial growth with the in situ dopants. After that, we heat up the wafer so dopants in the S/D can move toward the channel." A spike anneal does not destroy the silicon structure, he explained. While the ETSOI team is aiming for introduction at the 22 nm node ("All the ducks seem to be lining up," Doris said) the power of incumbency may keep IBM on partially depleted SOI until the 15 nm node. Pellerin, who manages the GlobalFoundries technology development team at Fishkill, said FD-SOI looks topographically similar to PD-SOI. "We are just dealing with a very thin body. It shares the processes we've grown accustomed to, and is good for channel characteristics." There is still the series resistance problem, and work is required to connect the source and drain to the channel. A raised S/D and other types of approaches have to be considered. "One challenge is: How do I reduce that parasitic resistance of that device?" Pellerin said. Gartner analyst Freeman said he believes that Intel and IBM will stick by their traditional guns, with Intel shying away from SOI substrates as long as possible and IBM pushing SOI as hard as it can. The Intel tri-gate structure, Freeman noted, "doesn't have to use SOI, because the area gets so small. There is still leakage at the substrate, but it is not a given that Intel has to go to SOI." Freeman's prediction is that "Intel will stretch bulk wafers as long as it can." IBM, on the other hand, will move as fast as is practical to fully depleted SOI. Both Soitec and Shin-Etsu Handotai (SEH, Tokyo) will be able to supply ETSOI wafers with the required specs, he said. FinFETs remain enticing FinFETs are another major path of investigation.3 Pellerin said ETSOI and finFETs also should be considered as a continuum, just as PD- and FD-SOI are. "I don't see one excluding the other. Both share some common advantages, and they also have their own unique set of integration challenges. To get to the transistor densities we will need, planar can only be shrunk so much. When we have to go to a finFET, it opens the door to an ability to achieve those transistor densities because we can pack vertical devices a lot closer together. FinFETs do have that additional knob of transistor density, to levels that planar would have difficulty in achieving."
4. FinFETs offer scaling advantages, but present manufacturing issues. (Source: IBM) FinFETs and tri-gate structures both involve "extra process complexity," Bohr said, but there is a payoff. Tri-gate structures have challenges with parasitic resistance and capacitance, but Bohr said Intel's tri-gate devices are demonstrating "better performance than any other published tri-gate or FinFET device." IBM doubled the number of R&D wafers on its finFET program in 2009 (Fig. 4), and the finFET effort is getting "really nice results," Doris said. "There are pros and cons of each one." A planar structure "is so comforting because it keeps the design style people are used to," he said. Although the width can be varied on planar transistors, with finFETs, "you have to add them up. There is no arbitrary width, so you quantize it and make more fins." Doris added, "I believe most people in the industry would agree that finFET processing is more difficult. Lithography is a huge challenge, though people can overcome that with sidewall image transfer." Etching the gate is another challenge. The gate wraps around the fin, making it difficult to characterize the profile of the gate. For there to be acceptable transistor characteristics, "the gate has to be as straight as possible," Doris said. In planar structures the gates lie in one plane, but "in finFETs, the gates are traversing the channel up and down all over your wafer. That poses some fundamental questions and approaches to how you integrate all the processes together to make that device," Doris said. When the gate wraps around the fin, it is difficult to optimize. "Much of the processing that the industry has used for the past 30 years can still be used on planar ETSOI," Doris said. "This industry tends to take very small steps. That's how we got to where we are. And that's why doing something fundamentally different like finFETs, at the same level of complexity, is hard to fathom in the near future." Pellerin said he has spoken to design customers about how prominent the design challenges to finFETs may be, in particular the "discretized device Ws." GlobalFoundries is targeting the 20 largest foundry customers, and they have not cited transistor width as a "showstopper or even a roadblock," Pellerin said. "We can offer multiple fins. Device designers don't use width as an analog kind of knob anyway. So while design with finFETs has been talked about, it is not panning out to be an issue at all." Freeman said although most companies are leery of finFETs because of the lithography and etching challenges of the vertical structures, "in one sense the epitaxial raised source/drain structures already are vertical in nature." SiC: yes or no? At 22 nm, it appears likely that one or more of the leaders will use the smaller-than-silicon carbon atoms to exert a tensile (pulling) stress on the silicon NMOS channel. The epitaxial structures on IBM's ETSOI process described at the recent International Electron Devices Meeting (IEDM), for example, use in situ doping to add SiC as a stressor on the NMOS devices. At the 2008 IEDM, and again at the 2009 Semicon West, the Fishkill Alliance partners, including Applied Materials, said they had demonstrated that SiC strain is workable. But has anyone committed to SiC? Pellerin said SiC is "an element we are looking at and considering for our 22 and below device architecture." Implanting the source/drain regions is becoming more complicated, and the SiC stressors are epitaxially grown, much like the SiGe strain regions on the pFETs. "Strain to the NMOS channel becomes another knob with which to improve performance," Pellerin said. Bohr has changed his tune somewhat on SiC stressors. In the past, he said Intel was leaning against SiC, but in an interview at the 2009 IEDM he said he didn't want to comment on the current status of SiC at Intel. Paul Packan, who presented Intel's 32 nm transistors at IEDM, also didn't reply to a question from the audience about SiC on the 32 nm NMOS devices. TSVs: Not only for memory Through-silicon vias (TSVs) and 3-D chip stacking are another technology that appears to be on the cusp of volume production. Already, IBM offers a fast SOI-based embedded DRAM capability, used on the Power 7 microprocessors and also offered to its foundry customers. TSV interconnected memory could be another weapon in IBM's unique technology arsenal of SOI, embedded SOI DRAM and, soon, TSV interconnects. Pellerin said TSVs will "definitely play a role" going forward, adding, "Embedded dense memory is an equally viable option and has a strong role to play. 3-D with TSVs is another approach to achieving that. And we shouldn't limit it to a logic chip mated to a memory. With TSVs, customers can really do heterogeneous types of integration that go beyond memory, enabling high-form-factor, high-function handheld devices. They can gain a lot of leverage in terms of what they can do in a small amount of space with heterogeneous die stacking using 3-D and TSVs." A role for heterogenous devices? By heterogeneous, Pellerin was referring to connecting logic with, say, optoelectronic or other devices that require a different material technology. Another meaning to the word heterogeneous is the use of a III-V transistor on the NMOS and a germanium transistor on the PMOS, for example. At the 2009 IEDM evening panel discussion, Krishna Saraswat, a professor at Stanford University, predicted that around the 10 nm channel length the industry will need to shift to new channel materials. Ideally, the industry will develop a decent III-V PMOS transistor to complement a III-V NMOS transistor, he said, a combination that would have "much lower power" consumption than silicon devices. "A III-V [NMOS] and germanium PMOS would be able to come in earlier that an all III-V solution, representing a good compromise," Saraswat said. Going forward, controlling power is the main challenge, said Raj Jammy, director of the front-end program at Sematech (Austin, Texas). "We need true high-performance devices with low power too. There is a blending or convergence going on," Jammy said, adding, "The beauty is that once we get to III-V devices, we can get to half of the operating voltages used today — to 0.5 V." Jammy led a Sematech workshop preceding IEDM on heterogeneous devices that combine a III-V (InGaAs is the most likely material set) device on the nFET, and perhaps a germanium channel on the pFET.4 The heterogeneous approach uses epitaxial techniques, depositing a III-V and germanium on a 300 mm wafer only in the critical circuits. For many university researchers, III-V-based devices are well-suited to the blending that may be needed. "III-Vs have made rapid progress in the last six months, more than many industry people realize," said T.P. Ma, a professor at Yale University. Some researchers, such as Akira Toriumi, now a University of Tokyo professor after a career at Toshiba Corp., argue that germanium channels can be used for both pFET and nFET devices.5 Jammy cautioned that "a germanium nFET is not easy, because of high contact resistance and high interface states."
5. Thus far, III-V devices have high mobility but face density issues. (Source: Intel) Robert Chau, director of transistor research and nanotechnology at Intel's Technology and Manufacturing Group in Hillsboro, Ore., said Intel has develop III-V n-channel devices (Fig. 5) with "very, very high mobility, significant gains in effective velocity and drain current. However, the footprint scalability remains an unknown."6 Professor Dimitri Antoniadis, who heads up the Marco Center and device research at the Massachusetts Institute of Technology (MIT, Cambridge, Mass.), said III-V transistors "will help on the speed and power vectors; the density vector is tricky. They may not help on gate length scaling; there is a lot more work that needs to be done on scalability." Thomas Skotnicki, a research manager at STMicroelectronics (Geneva), raised doubts about whether III-V devices will ever be introduced into mainstream ICs. "Silicon gives us the speed we need. At best, III-Vs will be limited to high-speed paths. The high-mobility materials might be introduced locally to improve variability, which is a key problem." References 1. P. Packan et al., "High Performance 32 nm Logic Technology Featuring 2nd Generation High-k + Metal Gate Transistors," 2009 IEDM Proc., p. 659. 2. G. Shahidi, "Device Architecture: Ultimate Planar CMOS Limit and Sub- 32nm Device Options," 2009 IEDM Short Course, p. 25. 3. K. Cheng et al., "Extremely Thin SOI (ETSOI) CMOS With Record Low Variability for Low Power System-on-Chip Applications," 2009 Proc., p. 49. 4. D. Lammers, "Silicon May Prevail Despite Power Fears," Semiconductor.net, Dec. 7, 2009. 5. C.H. Lee et al., "Record-High Electron Mobility in Ge n-MOSFETs Exceeding Si Universality," 2009 IEDM Proc., p. 457. 6. G. Dewey et al., "Logic Performance Evaluation and Transport Physics of Schottky-Gate III-V Compound Semiconductor Quantum Well Field Effect Transistors for Power Supply Voltages (VCC) Ranging From 0.5V to 1.0V," 2009 IEDM Proc., p. 487. |
| 小菜農(nóng)找的譯文和原文不一致呀 |
| 估計(jì)是cnbeta翻譯的不行。。。 |
| 不拉更的東西, 與我們和干? |
| 不拉更的東西, 與我們和干? |
