M. Lenski scite author profile

As transistor dimension becomes smaller and with the switch to high-k metal gate (HKMG) integration, the need for a sidewall protection layer that is conformal yet meets the low thermal budget requirement becomes critical. In this work, we evaluated PEALD SiN as spacer material in comparison to PECVD SiN, at two different stresses (compressive and tensile) and two different deposition temperatures. Material characterization reveals that PEALD SiN has lower hydrogen impurities, higher density and better resistance against wet chemistry, indicating superior material quality. In addition, film conformality and pattern density characteristics for all PEALD SiN films are significantly improved over PECVD SiN. These improvements in film characteristics help drive improvement in electrical properties for devices with PEALD SiN spacer.As transistor scaling continues and with the implementation of high-k metal gate (HKMG) in Complementary Metal-Oxide Semiconductor (CMOS), there is a critical need for a highly conformal sidewall protection layer. To prevent oxidation of the high-k layer and out diffusion of implants, the sidewall protection layer must be deposited at a relatively low deposition temperature. Furthermore, as transistor designs increase in complexity, this encapsulation layer or spacer must be conformal and not sensitive to wafer loading conditions. Traditionally, the spacer is deposited using chemical vapor deposition (CVD). 1,2 LPCVD SiN is known for having good conformality but its deposition occurs at high temperature (>700 • C). As the need arises for a spacer with a lower thermal budget, plasma enhanced CVD (PECVD) SiN has been used. With PECVD SiN, deposition temperature can be lowered to ∼400 • C. However, PECVD SiN has worse conformality compared to LPCVD SiN. Moreover, CVD processes are gas-phase reaction limited and thus the film growth is sensitive to loading conditions. As chip designs become more complex, with each chip having regions with different transistor densities, it is critical to have a spacer process that is not pattern density dependent.Atomic Layer Deposition (ALD) is a deposition technique which has a clear advantage of lower deposition temperature and excellent conformality. 3,4 The development of ALD SiN processes for various applications has been reported in the literature. Hong et al. reported ALD SiN layer and SiN/SiO 2 /SiN multi layers as a gate dielectric for flash memory. 6 For spacer application in 90 nm technology, it has been reported that using ALD SiO 2 and ALD SiN as spacer and silicide blocking layer resulted in improved short channel effects. The ALD SiN was deposited at 595 • C using dichlorosilane and NH 3 . 6 The main disadvantage of ALD compared to PECVD and LPCVD is its higher cost of ownership. This, however, is beyond the scope of this work.Plasma enhanced ALD (PEALD) has been gaining popularity and recently more new PEALD processes are being developed. 4,7-10 A comprehensive review article covering the basics of PEALD, its advantages and challenges had been ...

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Dual stress liner for high performance sub-45nm gate length SOI CMOS manufacturing

Yang¹,

Malik²,

Narasimha³

et al.

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Integration and optimization of embedded-sige, compressive and tensile stressed liner films, and stress memorization in advanced SOI CMOS technologies

Horstmann¹,

Wei²,

Kammler³

et al. 2005

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A quantitative analysis of stress-induced leakage currents and extraction of trap properties in 6.8 nm ultrathin silicon dioxide films

Endoh

Chiba

Sakuraba

et al. 1999

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Multiple Stress Memorization In Advanced SOI CMOS Technologies

Wei¹,

Wiatr²,

Mowry³

et al. 2007

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M. Lenski

Evaluation of Low Temperature Silicon Nitride Spacer for High-k Metal Gate Integration

Dual stress liner for high performance sub-45nm gate length SOI CMOS manufacturing

Integration and optimization of embedded-sige, compressive and tensile stressed liner films, and stress memorization in advanced SOI CMOS technologies

A quantitative analysis of stress-induced leakage currents and extraction of trap properties in 6.8 nm ultrathin silicon dioxide films

Multiple Stress Memorization In Advanced SOI CMOS Technologies

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