Phononics: Engineering and control of acoustic fields on a chip

Abstract: Micro and nanomechanical systems play an important role in modern science and technology.They are indispensable for precision sensing, navigation and communication. Over the past decade, the rapid advances in nano-fabrication and measurement science have enabled quantum control of mechanical devices by integrating them to optical and microwave cavities, in the growing field of quantum optomechanics. However, experiments in quantum optomechanics at room temperature still face significant challenges. Perhaps the… Show more

“…The non-uniform residual stress σ r of hetero-epitaxially grown 3C-SiC [23] allows us to investigate the dependence of the mean stress on film thickness σ(h). To find the relation σ(h), we measure the fundamental resonance frequency ω m of each fabricated trampoline from its noise power spectral density with an optical heterodyne detection system operating in vacuum (P ∼ 10 −6 mbar) as reported previously [30,34]. The quality factor Q is determined via a ringdown measurement after applying an impulse to the trampoline as shown in Fig.…”

“…In high-vacuum environments, the external energy dissipation is exclusively attributed to clamping losses Q −1 clamp [29], which we de- [21] and intrinsic friction in the volume of the material (Q −1 vol ) [37], and is detailed in Sec. IV C. Thermoelastic losses in highly stressed trampoline resonators were calculated [30] using existing models [38], and are neglected in the rest of this work due to their small contributions in thin resonators [39]. The total quality factor is given by…”

“…The radius of the clamping point is engineered to optimize the ratio of elastic energy stored as elongation as opposed to bending which is a source of losses [12,29], enhancing the Q by diluting the dissipation for the fundamental vibration mode. In this approach, two counteracting and competing mechanisms are present; the increased material volume at the widened clamps stores a larger amount of bending energy, while the increased rigidity reduces the overall bending [30,31]. The elongation to bending ratio converges to a maximum value for an optimum radius of curvature R. According to our finite element simulations, the optimal radius of curvature for our crystalline resonators is R = 30 µm, predicting a Q about four times larger compared to rigid clamping (R = 0).…”

Engineering the Dissipation of Crystalline Micromechanical Resonators

“…The non-uniform residual stress σ r of hetero-epitaxially grown 3C-SiC [23] allows us to investigate the dependence of the mean stress on film thickness σ(h). To find the relation σ(h), we measure the fundamental resonance frequency ω m of each fabricated trampoline from its noise power spectral density with an optical heterodyne detection system operating in vacuum (P ∼ 10 −6 mbar) as reported previously [30,34]. The quality factor Q is determined via a ringdown measurement after applying an impulse to the trampoline as shown in Fig.…”

“…In high-vacuum environments, the external energy dissipation is exclusively attributed to clamping losses Q −1 clamp [29], which we de- [21] and intrinsic friction in the volume of the material (Q −1 vol ) [37], and is detailed in Sec. IV C. Thermoelastic losses in highly stressed trampoline resonators were calculated [30] using existing models [38], and are neglected in the rest of this work due to their small contributions in thin resonators [39]. The total quality factor is given by…”

“…The radius of the clamping point is engineered to optimize the ratio of elastic energy stored as elongation as opposed to bending which is a source of losses [12,29], enhancing the Q by diluting the dissipation for the fundamental vibration mode. In this approach, two counteracting and competing mechanisms are present; the increased material volume at the widened clamps stores a larger amount of bending energy, while the increased rigidity reduces the overall bending [30,31]. The elongation to bending ratio converges to a maximum value for an optimum radius of curvature R. According to our finite element simulations, the optimal radius of curvature for our crystalline resonators is R = 30 µm, predicting a Q about four times larger compared to rigid clamping (R = 0).…”

Engineering the Dissipation of Crystalline Micromechanical Resonators