COSMOS架构中的设备缩放

A. Al-Ahmadi, S. Kaya
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In this paper we demonstrate and design, through the use of 1/2/3D device simulations, a novel symmetrically operating CMOS device pair with a single gate structure having a unique device layout and ultra-thin strained channels [4]. The new architecture, named complementary orthogonal stacked MOS (COSMOS), places the n and pMOSFETs perpendicular to one another under a single gate, integrating them vertically (see Figs.1&2). Thus COSMOS can eliminate the aforementioned redundancy in CMOS and may result in dramatic savings (>50%) not only in active device area of a conventional digital CMOS layout, but also in R-C device parasitics associated with building and wiring two sets of devices for a single Boolean output function. We argue that the COSMOS structure is a natural candidate for very dense, low-power circuitry required in sub-5Onm scale. The proposed COSMOS architecture relies for operation on a conventional silicon electron channel grown atop a strained-SiGe channel for holes, as shown in Fig.2. To facilitate threshold tuning, reduce parallel conduction and eliminate need for doping, Ge concentration in the strained channel must be high. In accordance, the gate material may be a mid-gap metal, poly-SiGe alloy or polySi, depending on the choice of Ge concentration or background doping. The channel layers must be grown [5] or bonded [6] on a SOI substrate to allow isolation of both MOSFETs, while also keeping with the general scaling trends associated with low-leakage and low-parasitic SOI substrates. For a sample layer structure with a 4nm strained-Si03Ge0.7 hole channel and 3nm Si electron channel under a mid-gap metal gate, ID self-consistent Poisson-Schrodinger simulations (see Fig.3) indicate that symmetric population of both channels is possible with a threshold of IVTI=0.4±0.2 V. We also find that there is no significant parallel conduction in this layer structure, removing concerns for isolation in the stacked channels. Even for this non-optimum layer example, the carriers in both channels of COSMOS layers are well confined and have quite similar distributions. The use of large Ge concentration in the buried strained channel should improve hole mobility considerably over that of electrons in Si inversion channel. Thus, for x.0.3, hole mobility in strained Sii-.Gex layers should be comparable to or larger than electron mobility in undoped Si inversion layer [7]. By aligning p-MOSFET along the [011] direction [8], hole mobility may be further improved, thus restoring p-MOSFET transconductance deficit due to larger separation from the gate. In COSMOS, there are several independent parameters of layer structure, including layer composition, thickness and order, which can be used to optimize a symmetric device threshold. In Fig.4, we demonstrate how these parameters can be independently tailored to prevent parallel conduction and to set VT accurately. 3D TCAD simulations of the individual MOSFET characteristics (Fig.5) validate the ID analysis above, providing further support for the ability of symmetric control of two channels with a single gate. To show the usefulness of COSMOS for digital circuits, we simulated in 3D the transient response of a 40nm COSMOS NOT gate to an input pulse (Fig.6). The gate has respectable delay (lO00ps) and noise margin figures at low drive voltages (VDD+IVssl< .OV) used in sub-SOnm scale. These results illustrate the unique potential of COSMOS logic for low-power and high-density applications, which can be further enhanced by optimizing the structure and choice of symmetric VT. The delay of the gate can be improved at the expense of static leakage (Fig.7) due to parasitic p-i-n device turning on at highdrive conditions. To inhibit this, two additional etching steps are required during the fabrication of COSMOS structure [4]. Furthermore, the COSMOS gates have peculiar scaling trends, with smaller gate lengths having larger thresholds and smaller ON current below 20nm nodes due to reciprocal dependency of gate length and width in orthogonal device layout (Fig.8). The present study is an attempt at presenting how the novel COSMOS architecture can be operated, optimized and utilized in sub-50nm. We illustrate the design principles of this so far unexplored COSMOS architecture for optimum leakage and switching performance. This work shows how significant area and performance gains can be obtained in CMOS logic circuits by a unique combination of layout and channel engineering,","PeriodicalId":306160,"journal":{"name":"63rd Device Research Conference Digest, 2005. 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While these structures have unique features superior to conventional bulk devices, nonetheless, they still retain the redundancy inherent to CMOS operation, namely building two devices even though only one operates at a given stable output. In this paper we demonstrate and design, through the use of 1/2/3D device simulations, a novel symmetrically operating CMOS device pair with a single gate structure having a unique device layout and ultra-thin strained channels [4]. The new architecture, named complementary orthogonal stacked MOS (COSMOS), places the n and pMOSFETs perpendicular to one another under a single gate, integrating them vertically (see Figs.1&2). Thus COSMOS can eliminate the aforementioned redundancy in CMOS and may result in dramatic savings (>50%) not only in active device area of a conventional digital CMOS layout, but also in R-C device parasitics associated with building and wiring two sets of devices for a single Boolean output function. We argue that the COSMOS structure is a natural candidate for very dense, low-power circuitry required in sub-5Onm scale. The proposed COSMOS architecture relies for operation on a conventional silicon electron channel grown atop a strained-SiGe channel for holes, as shown in Fig.2. To facilitate threshold tuning, reduce parallel conduction and eliminate need for doping, Ge concentration in the strained channel must be high. In accordance, the gate material may be a mid-gap metal, poly-SiGe alloy or polySi, depending on the choice of Ge concentration or background doping. The channel layers must be grown [5] or bonded [6] on a SOI substrate to allow isolation of both MOSFETs, while also keeping with the general scaling trends associated with low-leakage and low-parasitic SOI substrates. For a sample layer structure with a 4nm strained-Si03Ge0.7 hole channel and 3nm Si electron channel under a mid-gap metal gate, ID self-consistent Poisson-Schrodinger simulations (see Fig.3) indicate that symmetric population of both channels is possible with a threshold of IVTI=0.4±0.2 V. We also find that there is no significant parallel conduction in this layer structure, removing concerns for isolation in the stacked channels. Even for this non-optimum layer example, the carriers in both channels of COSMOS layers are well confined and have quite similar distributions. The use of large Ge concentration in the buried strained channel should improve hole mobility considerably over that of electrons in Si inversion channel. Thus, for x.0.3, hole mobility in strained Sii-.Gex layers should be comparable to or larger than electron mobility in undoped Si inversion layer [7]. By aligning p-MOSFET along the [011] direction [8], hole mobility may be further improved, thus restoring p-MOSFET transconductance deficit due to larger separation from the gate. In COSMOS, there are several independent parameters of layer structure, including layer composition, thickness and order, which can be used to optimize a symmetric device threshold. In Fig.4, we demonstrate how these parameters can be independently tailored to prevent parallel conduction and to set VT accurately. 3D TCAD simulations of the individual MOSFET characteristics (Fig.5) validate the ID analysis above, providing further support for the ability of symmetric control of two channels with a single gate. To show the usefulness of COSMOS for digital circuits, we simulated in 3D the transient response of a 40nm COSMOS NOT gate to an input pulse (Fig.6). The gate has respectable delay (lO00ps) and noise margin figures at low drive voltages (VDD+IVssl< .OV) used in sub-SOnm scale. 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引用次数: 0

摘要

硅纳米电子工程最近已经达到了一定的能力水平,这使得在绝缘体上硅(SOI)衬底上进行三维加工和应变工程不仅成为可能[1,2],而且是克服传统平面CMOS实际限制的必要条件[3]。因此,器件设计人员在探索新设计时提供了多种选择,如替代架构的激增,包括多门控,应变Si/SiGe通道,肖特基和隧道mosfet。虽然这些结构具有优于传统批量器件的独特功能,但它们仍然保留了CMOS操作固有的冗余性,即即使只有一个器件在给定的稳定输出下工作,也可以构建两个器件。在本文中,我们通过使用1/2/3D器件模拟演示和设计了一种具有独特器件布局和超薄应变通道的单栅极结构的新型对称操作CMOS器件对[4]。新的结构,称为互补正交堆叠MOS (COSMOS),将n和pmosfet垂直放置在一个栅极下,垂直集成它们(见图1和图2)。因此,COSMOS可以消除CMOS中的上述冗余,不仅可以节省传统数字CMOS布局的有源器件面积(>50%),还可以节省与为单个布尔输出功能构建和连接两组器件相关的R-C器件寄生。我们认为COSMOS结构是sub-5Onm尺度下所需的非常密集、低功耗电路的自然候选。所提出的COSMOS架构依赖于传统的硅电子通道来运行,该通道生长在应变sige孔道之上,如图2所示。为了便于阈值调谐,减少平行传导和消除掺杂的需要,应变通道中的Ge浓度必须很高。根据锗浓度或背景掺杂的选择,栅极材料可以是中隙金属、聚sige合金或多晶硅。沟道层必须在SOI衬底上生长[5]或键合[6],以允许两个mosfet隔离,同时也保持与低漏和低寄生SOI衬底相关的一般缩放趋势。对于在中隙金属栅下具有4nm应变si03ge0.7孔道和3nm Si电子通道的样品层结构,ID自一致泊松-薛定谔模拟(见图3)表明,当阈值为IVTI=0.4±0.2 V时,两个通道可以对称填充。我们还发现在该层结构中没有明显的平行传导,消除了对堆叠通道隔离的担忧。即使对于这个非最优层的例子,COSMOS层的两个通道中的载流子也受到很好的限制,并且具有非常相似的分布。在埋藏应变沟道中使用高浓度的Ge,将大大提高电子在Si反转沟道中的空穴迁移率。因此,当x.0.3时,应变Sii-的空穴迁移率。Gex层应相当于或大于未掺杂Si反转层中的电子迁移率[7]。通过将p-MOSFET沿[011]方向对齐[8],可以进一步提高空穴迁移率,从而恢复p-MOSFET由于与栅极分离较大而产生的跨导亏损。在COSMOS中,有几个独立的层结构参数,包括层组成、厚度和顺序,可以用来优化对称器件阈值。在图4中,我们演示了如何独立定制这些参数以防止并联导通并准确设置VT。单个MOSFET特性的3D TCAD仿真(图5)验证了上面的ID分析,进一步支持了用单栅极对称控制两个通道的能力。为了证明COSMOS在数字电路中的实用性,我们在3D中模拟了40nm COSMOS NOT门对输入脉冲的瞬态响应(图6)。该栅极在sub-SOnm尺度下使用的低驱动电压(VDD+IVssl< . ov)下具有可观的延迟(lO00ps)和噪声裕度数字。这些结果说明了COSMOS逻辑在低功耗和高密度应用中的独特潜力,可以通过优化结构和选择对称VT进一步增强。栅极的延迟可以以静态泄漏为代价得到改善(图7),这是由于寄生p-i-n器件在高驱动条件下开启造成的。为了抑制这种情况,在COSMOS结构的制造过程中需要两个额外的蚀刻步骤[4]。此外,COSMOS栅极具有特殊的缩放趋势,由于正交器件布局中栅极长度和宽度的相互依赖,栅极长度越小,阈值越大,20nm以下节点的ON电流越小(图8)。本研究旨在介绍新型COSMOS架构如何在50nm以下操作、优化和利用。 我们说明了这种迄今为止尚未开发的COSMOS架构的设计原则,以获得最佳的泄漏和开关性能。这项工作表明,通过独特的布局和通道工程组合,可以在CMOS逻辑电路中获得显着的面积和性能增益。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Device scaling in COSMOS architecture
The Si nanoelectronic engineering have recently reached a level of capability, which make 3D processing and strain engineering on silicon-on-insulator (SOI) substrates not only possible [1,2], but also a necessity in order to surmount practical limitations of conventional planar CMOS [3]. Thus, device designers are presented with a multitude of options in exploring new designs, as evident in the proliferation of alternative architectures, including multi-gated, strained Si/SiGe channel, Schottky and Tunneling MOSFETs. While these structures have unique features superior to conventional bulk devices, nonetheless, they still retain the redundancy inherent to CMOS operation, namely building two devices even though only one operates at a given stable output. In this paper we demonstrate and design, through the use of 1/2/3D device simulations, a novel symmetrically operating CMOS device pair with a single gate structure having a unique device layout and ultra-thin strained channels [4]. The new architecture, named complementary orthogonal stacked MOS (COSMOS), places the n and pMOSFETs perpendicular to one another under a single gate, integrating them vertically (see Figs.1&2). Thus COSMOS can eliminate the aforementioned redundancy in CMOS and may result in dramatic savings (>50%) not only in active device area of a conventional digital CMOS layout, but also in R-C device parasitics associated with building and wiring two sets of devices for a single Boolean output function. We argue that the COSMOS structure is a natural candidate for very dense, low-power circuitry required in sub-5Onm scale. The proposed COSMOS architecture relies for operation on a conventional silicon electron channel grown atop a strained-SiGe channel for holes, as shown in Fig.2. To facilitate threshold tuning, reduce parallel conduction and eliminate need for doping, Ge concentration in the strained channel must be high. In accordance, the gate material may be a mid-gap metal, poly-SiGe alloy or polySi, depending on the choice of Ge concentration or background doping. The channel layers must be grown [5] or bonded [6] on a SOI substrate to allow isolation of both MOSFETs, while also keeping with the general scaling trends associated with low-leakage and low-parasitic SOI substrates. For a sample layer structure with a 4nm strained-Si03Ge0.7 hole channel and 3nm Si electron channel under a mid-gap metal gate, ID self-consistent Poisson-Schrodinger simulations (see Fig.3) indicate that symmetric population of both channels is possible with a threshold of IVTI=0.4±0.2 V. We also find that there is no significant parallel conduction in this layer structure, removing concerns for isolation in the stacked channels. Even for this non-optimum layer example, the carriers in both channels of COSMOS layers are well confined and have quite similar distributions. The use of large Ge concentration in the buried strained channel should improve hole mobility considerably over that of electrons in Si inversion channel. Thus, for x.0.3, hole mobility in strained Sii-.Gex layers should be comparable to or larger than electron mobility in undoped Si inversion layer [7]. By aligning p-MOSFET along the [011] direction [8], hole mobility may be further improved, thus restoring p-MOSFET transconductance deficit due to larger separation from the gate. In COSMOS, there are several independent parameters of layer structure, including layer composition, thickness and order, which can be used to optimize a symmetric device threshold. In Fig.4, we demonstrate how these parameters can be independently tailored to prevent parallel conduction and to set VT accurately. 3D TCAD simulations of the individual MOSFET characteristics (Fig.5) validate the ID analysis above, providing further support for the ability of symmetric control of two channels with a single gate. To show the usefulness of COSMOS for digital circuits, we simulated in 3D the transient response of a 40nm COSMOS NOT gate to an input pulse (Fig.6). The gate has respectable delay (lO00ps) and noise margin figures at low drive voltages (VDD+IVssl< .OV) used in sub-SOnm scale. These results illustrate the unique potential of COSMOS logic for low-power and high-density applications, which can be further enhanced by optimizing the structure and choice of symmetric VT. The delay of the gate can be improved at the expense of static leakage (Fig.7) due to parasitic p-i-n device turning on at highdrive conditions. To inhibit this, two additional etching steps are required during the fabrication of COSMOS structure [4]. Furthermore, the COSMOS gates have peculiar scaling trends, with smaller gate lengths having larger thresholds and smaller ON current below 20nm nodes due to reciprocal dependency of gate length and width in orthogonal device layout (Fig.8). The present study is an attempt at presenting how the novel COSMOS architecture can be operated, optimized and utilized in sub-50nm. We illustrate the design principles of this so far unexplored COSMOS architecture for optimum leakage and switching performance. This work shows how significant area and performance gains can be obtained in CMOS logic circuits by a unique combination of layout and channel engineering,
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