Effect of Native Oxide on Stress in Silicon Nanowires: Implications for Nanoelectromechanical Systems

Yusuf Leblebici, Mohammad Nasr Esfahani, Zuhal Tasdemir
AMER CHEMICAL SOC, 2022
Journal paper

Abstract

Understanding the origins of intrinsic stress in Si nanowires (NWs) is crucial for their successful utilization as transducer building blocks in next-generation, miniaturized sensors based on nanoelectromechanical systems (NEMS). With their small size leading to ultrahigh-resonance frequencies and extreme surface-to-volume ratios, silicon NWs raise new opportunities regarding sensitivity, precision, and speed in both physical and biochemical sensing. With silicon optoelectromechanical properties strongly dependent on the level of NW intrinsic stress, various studies have been devoted to the measurement of such stresses generated, for example, as a result of harsh fabrication processes. However, due to enormous NW surface area, even the native oxide that is conventionally considered as a benign surface condition can cause significant stresses. To address this issue, a combination of nanomechanical characterization and atomistic simulation approaches is developed. Relying only on low-temperature processes, the fabrication approach yields monolithic NWs with optimum boundary conditions, where NWs and support architecture are etched within the same silicon crystal. Resulting NWs are characterized by transmission electron microscopy and micro-Raman spectroscopy. The interpretation of results is carried out through molecular dynamics simulations with ReaxFF potential facilitating the incorporation of humidity and temperature, thereby providing a close replica of the actual oxidation environment-in contrast to previous dry oxidation or self-limiting thermal oxidation studies. As a result, consensus on significant intrinsic tensile stresses on the order of 100 MPa to 1 GPa was achieved as a function of NW critical dimension and aspect ratio. The understanding developed herein regarding the role of native oxide played in the generation of NW intrinsic stresses is important for the design and development of silicon-based NEMS.

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Yusuf Leblebici, Mohammad Nasr Esfahani, Zuhal Tasdemir
AMER CHEMICAL SOC, 2022
Journal paper

Abstract

Official source

https://infoscience.epfl.ch/record/297270?ln=en

About this result

Related concepts (14)

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Multi-scale integration remains the primary challenge in the fabrication of miniature piezoresistive sensors, as the co-fabrication of a silicon nanowire along with a microscale shuttle is the main architecture facilitating high-sensitivity transduction. The efforts in this field are marred by the lack of batch techniques compatible with semiconductor manufacturing. A technology is introduced here that leads to the fabrication of a piezoresistive silicon nanowire sharing the same single-crystalline device layer of a thick silicon-on-insulator wafer as the microscale component. The approach is based on a combination of high-resolution lithography with a two-stage etching process. The demonstration is carried out by spanning an electrostatic comb-drive actuator and a micromechanical amplifier by a single nanowire. A gage factor range of 135-145 is obtained, corresponding to an almost 20% resistance change for a nanowire strain of 1.26 x 10(-3). The technique is shown to generate a two-order-of-magnitude scale difference within the same silicon crystal. It also provides ease of electrical access to the nanowire, as the nanowire does not remain buried underneath the thick micromechanical system. With the associated lack of high-temperature processes and its CMOS-compatibility, the technique is a promising enabler for future miniaturized piezoresistive sensors. [2017-0007]

Institute of Electrical and Electronics Engineers2017

Piezoresistivity characterization of silicon nanowires through monolithic MEMS

Yusuf Leblebici, Mohammad Nasr Esfahani

This paper presents a monolithic approach for the integration of silicon nanowires (Si NWs) with microelectromechanical systems (MEMS). The process is demonstrated for the case of co-fabrication of Si NWs with a 10-μm-thick MEMS on the same silicon-on-insulator (SOI) wafer. MEMS is designed in the form of a characterization platform with an electrostatic actuator and a mechanical amplifier spanned by a single Si NW. This integrated platform is utilized for the successful measurement of Si NW piezoresistive gauge factor (GF) under a uniform uniaxial stress. Available techniques in this field include: Indirect (substrate) or direct (actuator) bending of Si NW necessitating rigorous models for the conversion of load to stress, inanomanipulation and attachment of Si NW on MEMS, a non-monolithic technique posing residual stress and alignment issues, and heterogeneous integration with separate Si layers for Si NW and MEMS, where a single SOI is not sufficient for the end product. Providing a monolithic solution to the integration of micro and nanoscale components, the presented technique successfully addresses the shortcomings of similar studies. In addition to providing a solution for electromechanical characterization, the technique also sets forth a promising pathway for multiscale, functional devices produced in a batch-compatible fashion, as it facilitates co-fabrication within the same Si crystal.

2017

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The synthesis of silicon nanowires by Ga-assisted plasma enhanced chemical vapor deposition (PECVD) has been recently demonstrated. In the present work, we study in detail the structural characteristics of the synthesized nanowires. High resolution transmission electron microscopy (HRTEM) analysis reveals the existence of various types of structural defects, which can be classified mainly according to the orientation into axial twins, lateral twins, and transverse twins. We compare our results with previous studies of Si nanowires synthesized with other catalyst metals. Understanding, both the origin and the effects of the observed defects is important for technological applications. The presence of twinned domains changes locally the structure of the material. As a consequence, one should find a different local density of states and band gap, which should result in a variation of the carrier transport and optical properties of the nanowires.

American Chemical Society2010