Experimental observation and analytical model of the stress gradient inversion in 3C-SiC layers on silicon

Zieliński, Marcin; Michaud, Jean-François; Jiao, S.; Chassagne, Thierry; Bazin, Anne-Elisabeth; Michon, A.; Portail, Marc; Alquier, Daniel

doi:10.1063/1.3687370

Cited by 25 publications

(24 citation statements)

References 27 publications

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“…Note that this finding is potentially in agreement with the work by Zielinski and coworkers. [39][40][41] They investigated cantilever bending for SiC with thicknesses from 100 nm to above 1 µm and shown constant upward bending in SiC(111) as we report, but only downward bending in SiC(100). As we show here, the upward bending of SiC(100) is restricted to a narrow region, i.e.…”

Section: A Stress Relaxation Mechanism Upon Growthsupporting

confidence: 62%

Controlling the intrinsic bending of hetero-epitaxial silicon carbide micro-cantilevers

Kermany

Iacopi

2015

Journal of Applied Physics

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We introduce a simple methodology to predict and tailor the intrinsic bending of a cantilever made of a single thin film of hetero-epitaxial silicon carbide grown on silicon. The combination of our novel method for the depth profiling of residual stress with a few nm resolution with finite element modelling allows for the prediction of the bending behaviour with great accuracy. We also demonstrate experimentally that a silicon carbide cantilever made of one distinct film type can be engineered to obtain the desired degree of either upward, flat, or downward bending, by selecting the appropriate thickness and cantilever geometry. A precise control of cantilever bending is crucial for MEMS applications such as micro-actuators, micro-switches, and resonant sensors. I. INTRODUCTION Epitaxial cubic silicon carbide (3C-SiC) is a leading material for micro electrical mechanical systems (MEMS) due to its excellent mechanical properties when silicon (Si) has limitations. 1-4 Furthermore, it can be grown on Si substrate which results in large area, easy micromachining, and low cost production.

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Section: A Stress Relaxation Mechanism Upon Growthsupporting

confidence: 62%

Controlling the intrinsic bending of hetero-epitaxial silicon carbide micro-cantilevers

Kermany

Iacopi

2015

Journal of Applied Physics

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“…where λ n is a constant depending of the mode (λ 1 = 1.875, λ 2 = 4.694), h and L are, respectively, the thickness and the length of the beam, E the Young's modulus and ρ the cantilever material density (3.2 g cm -3 for SiC). Indeed, as mentioned previously, the use of this method has highlighted the fact that 3C-SiC (100) cantilevers are bended downwards whereas 3C-SiC (111) cantilevers are bended upwards, which is clearly visible on submicron-thick cantilevers, and reveal opposite residual stress effects [68,106].…”

Section: Mems Devices and Mechanical Propertiesmentioning

confidence: 66%

3C-SiC — From Electronic to MEMS Devices

Michaud¹,

Portail²,

Alquier³

2015

Advanced Silicon Carbide Devices and Processing

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Since decades, silicon carbide (SiC) has been avowed as an interesting material for highpower and high-temperature applications because of its significant properties including its wide bandgap energy and high temperature stability. SiC is also professed as an ideal candidate for microsystem applications due to its excellent mechanical properties and chemical inertia, making it suitable for harsh environments. Among the 250 different SiC polytypes, only 4H, 6H and 3C-SiC are commercially available. The cubic structure, 3C-SiC, is the only one that can be grown on cheap silicon substrates. Hence, 3C-SiC is more interesting than any other polytype for reducing fabrication costs and increasing wafer diameter. This huge property has been evidenced for more than 30 years using chemical vapor deposition. Despite this key achievement and the growing interest for silicon carbide, no 3C-SiC-based devices can be found on the market whereas 4H-SiCbased devices are more and more largely commercialized. Even so, important headways have been reached for electrical and microelectromechanical systems (MEMS) applications. Therefore, the purpose of this chapter is to address concerns related to electronic applications and MEMS fabrication of 3C-SiC-based devices, trying to give a broad overview on specific issues and challenging solutions.

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“…29,37 In addition, the lattice and thermal expansion mismatches between Si and SiC result in the formation of defects and residual stress within the epitaxial SiC film. [37][38][39] We have previously shown that we could achieve f n Â Q product of $10 12 (Hz) with large absorption area through the application of cubic silicon carbide (3C-SiC) microstrings with high intrinsic tensile mean stress, which outperforms the highest reported state of the art silicon nitride (a-Si 3 N 4 ) microstrings and offer high promise for chemical sensing. 29 In this work, we explore the factors affecting the R Â Q and f n Â Q products of the fundamental out-of-plane flexural mode of 3C-SiC microstrings, including the film quality, residual mean stress (r), geometry, clamping condition, and environmental pressure.…”

Section: Introductionmentioning

confidence: 99%

Factors affecting the f × Q product of 3C-SiC microstrings: What is the upper limit for sensitivity?

Kermany

Bennett

Brawley

et al. 2016

Journal of Applied Physics

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Experimental observation and analytical model of the stress gradient inversion in 3C-SiC layers on silicon

Cited by 25 publications

References 27 publications

Controlling the intrinsic bending of hetero-epitaxial silicon carbide micro-cantilevers

Controlling the intrinsic bending of hetero-epitaxial silicon carbide micro-cantilevers

3C-SiC — From Electronic to MEMS Devices

Factors affecting the f × Q product of 3C-SiC microstrings: What is the upper limit for sensitivity?

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