Villanueva L G, Schmid S
Advanced NEMS Group, École Polytechnique Fédérale de Lausanne (EPFL), CH-1015 Lausanne, Switzerland.
Department of Micro-and Nanotechnology, Technical University of Denmark, DTU Nanotech, DK-2800 Kongens Lyngby, Denmark.
Phys Rev Lett. 2014 Nov 28;113(22):227201. doi: 10.1103/PhysRevLett.113.227201. Epub 2014 Nov 25.
Silicon nitride (SiN) micro- and nanomechanical resonators have attracted a lot of attention in various research fields due to their exceptionally high quality factors (Qs). Despite their popularity, the origin of the limiting loss mechanisms in these structures has remained controversial. In this Letter we propose an analytical model combining acoustic radiation loss with intrinsic loss. The model accurately predicts the resulting mode-dependent Qs of low-stress silicon-rich and high-stress stoichiometric SiN membranes. The large acoustic mismatch of the low-stress membrane to the substrate seems to minimize radiation loss and Qs of higher modes (n∧m≥3) are limited by intrinsic losses. The study of these intrinsic losses in low-stress membranes reveals a linear dependence with the membrane thickness. This finding was confirmed by comparing the intrinsic dissipation of arbitrary (membranes, strings, and cantilevers) SiN resonators extracted from literature, suggesting surface loss as ubiquitous damping mechanism in thin SiN resonators with Q_{surf}=βh and β=6×10^{10}±4×10^{10} m^{-1}. Based on the intrinsic loss the maximal achievable Qs and Qf products for SiN membranes and strings are outlined.
由于其极高的品质因数(Qs),氮化硅(SiN)微纳机械谐振器在各个研究领域引起了广泛关注。尽管它们很受欢迎,但这些结构中限制损耗机制的起源仍存在争议。在这封信中,我们提出了一个将声辐射损耗与固有损耗相结合的分析模型。该模型准确地预测了低应力富硅和高应力化学计量比SiN膜所产生的与模式相关的Qs。低应力膜与衬底之间较大的声失配似乎使辐射损耗最小化,并且高阶模式(n∧m≥3)的Qs受固有损耗限制。对低应力膜中这些固有损耗的研究揭示了其与膜厚度的线性关系。通过比较从文献中提取的任意(膜、弦和悬臂梁)SiN谐振器的固有耗散,证实了这一发现,表明表面损耗是薄SiN谐振器中普遍存在的阻尼机制,Q_{surf}=βh且β = 6×10^{10}±4×10^{10} m^{-1}。基于固有损耗,概述了SiN膜和弦可实现的最大Qs和Qf乘积。
