Sidewall transfer process and selective gate sidewall spacer formation technology for sub-15nm finfet with elevated source/drain extension

Kaneko, A.; Yagishita, Akira; Yahashi, K.; Kubota, T.; Omura, Mitsuhiro; Matsuo, K.; Mizushima, Ichiro; Okano, K.; Kawasaki, H.; Inaba, S.; Izumida, T.; Kondo, Takahisa; Aoki, Naofumi; Ishimaru, K.; Ishiuchi, H.; Suguro, K.; Eguchi, Kazuhiro; Tsunashima, Y.

doi:10.1109/iedm.2005.1609488

Cited by 36 publications

(29 citation statements)

References 8 publications

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“…Then, the gate oxide is formed by dry oxidation in furnace. After gate oxidation, the gateto-substrate isolation oxide could be deposited by high density plasma chemical vapor deposition (HDPCVD) as STI formation [11], [12]. Therefore, the thicknesses of isolation oxide and top-gate oxide are about the same as shown in inset of Fig.…”

Section: Bulk Finfet Structurementioning

confidence: 97%

A pragmatic design methodology using proper isolation and doping for bulk FinFETs

Liao

Chiang

Lai

et al. 2013

Solid-State Electronics

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Section: Bulk Finfet Structurementioning

confidence: 97%

A pragmatic design methodology using proper isolation and doping for bulk FinFETs

Liao

Chiang

Lai

et al. 2013

Solid-State Electronics

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“…IBM has fabricated and investigated FINFET devices with traditional gate stack for the 22 nm technology node and estimated the weakness from capacitance point of view, with a Cgs minimizing scheme proposed [122] . Fin patterning based on spacer technology has been proposed for fine Fin control [117] . Novel SiBCN low K spacer technology and spacer removal method have been demonstrated as examples for parasitic capacitance reduction [124,125] .…”

Section: Non-planar Finfetmentioning

confidence: 99%

Challenges of 22 nm and beyond CMOS technology

Huang

Kang

et al. 2009

Sci. China Ser. F-Inf. Sci.

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It is predicted that CMOS technology will probably enter into 22 nm node around 2012. Scaling of CMOS logic technology from 32 to 22 nm node meets more critical issues and needs some significant changes of the technology, as well as integration of the advanced processes. This paper will review the key processing technologies which can be potentially integrated into 22 nm and beyond technology nodes, including double patterning technology with high NA water immersion lithography and EUV lithography, new device architectures, high K/metal gate (HK/MG) stack and integration technology, mobility enhancement technologies, source/drain engineering and advanced copper interconnect technology with ultra-low-k process.

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“…Many of these papers discuss the use of CMP in the fabrication of Finfets. Figure 20.11 [9] shows how Toshiba researchers use CMP to planarize the surface between fin formation and gate formation. Planarization here is required in order to provide a uniform depth of focus for polygate lithography.…”

Section: Finfet Transistorsmentioning

confidence: 99%

CMP—The Next Fifteen Years

Steigerwald

2007

Microelectronic Applications of Chemical Mechanical Planarization

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In the early 1990s, reports by some IC manufacturers on the use of silicon wafer polishers to reduce the topography in interlevel dielectric (ILD) films created by multiple levels of metallization began to surface. Dismissed at first as irrational, such reports eventually proved to be true as the CMP industry began gaining ground. By the end of the decade, feature densities approaching sub-100 nm demanded not only an ILD CMP but CMP steps in the front end of the line (FEOL) as well. Process designers referred to CMP reverently as an enabling technology because the planarity it afforded was required for submicron lithography and multilevel metallization. But CMP engineers and integrators regarded the new process as more of a necessary evil because of the many challenges associated with controlling the new technology in high volume manufacturing. These conflicting perceptions of CMP as an enabling technology that is difficult to manage have persisted throughout CMP's more than 15 years' history. Table 20.1 shows the technology node and the year in which the manufacturing of key CMP processes was introduced at Intel Corporation. These CMP processes, while enabling different aspects of IC technology, shared several key features. First and foremost, they were all revolutionary technologies in that they (1) significantly advanced in the state of the art, (2) required significant capital investment, and (3) required significant development efforts to make them work. An additional feature that the CMP processes shared was that they were unique solutions as, for most of them, there was no viable alternative to their use-these CMP steps were required.

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Sidewall transfer process and selective gate sidewall spacer formation technology for sub-15nm finfet with elevated source/drain extension

Cited by 36 publications

References 8 publications

A pragmatic design methodology using proper isolation and doping for bulk FinFETs

A pragmatic design methodology using proper isolation and doping for bulk FinFETs

Challenges of 22 nm and beyond CMOS technology

CMP—The Next Fifteen Years

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