Propagation and Imaging of Mechanical Waves in a Highly Stressed Single-Mode Acoustic Waveguide
Erick Romero,
Rachpon Kalra,
Nicholas P. Mauranyapin,
Christopher G. Baker,
Chao Meng,
Warwick P. Bowen
May 2019
Abstract
We demonstrate a single-mode acoustic waveguide that enables robust propagation of mechanical waves. The waveguide is a highly stressed silicon-nitride membrane that supports the propagation of out-of-plane modes. In direct analogy to rectangular microwave waveguides, there exists a band of frequencies over which only the fundamental mode is allowed to propagate, while multiple modes are supported at higher frequencies. We directly image the mode profiles using optical heterodyne vibration measurement, showing good agreement with theory. In the single-mode frequency band, we show low-loss propagation (approximately 1 dB/cm) for an approximately 5-MHz mechanical wave. This design is well suited for acoustic circuits interconnecting elements such as nonlinear resonators or optomechanical devices for signal processing, sensing, or quantum technologies.
Publication
In Physical Review Applied
Senior Process Development Engineer
Erick Romero received his Ph.D. in Physics from the University of Queensland in Australia. As a postdoctoral fellow his research focuses on the fundamental origins of nanomechanical dissipation. His current research ranges from high precision sensors, nanomechanical computing, and nanomechanical hybrid systems. His research has been supported by CONACYT, the Australian Research Council, Lockheed Martin and the Australian Defence Science and Technology Group. He currently works at the Australian National Fabrication Facility supporting and developing nanofabrication processes. Contact him below if you would like to get in touch about nanofabrication.