Optimization and Artifacts of Photothermal Excitation of Microresonators

Liping Kevin Ge, Alessandro Tuniz, C. Martijn de Sterke, James M. Zavislan, Thomas G. Brown, Sascha Martin, David Martinez-Martin
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Abstract

The excitation of microresonators using focused intensity modulated light, known as photothermal excitation, is gaining significant attention due to its capacity to accurately excite microresonators without distortions, even in liquid environments, which is driving key advancements in atomic force microscopy and related technologies. Despite progress in the development of coatings, the conversion of light into mechanical movement remains largely inefficient, limiting resonator movements to tens of nanometers even when milliwatts of optical power are used. Moreover, how photothermal efficiency depends on the relative position of a microresonator along the propagation axis of the photothermal beam remains poorly studied, hampering the understanding of the conversion of light into mechanical motion. Here, photothermal measurements are performed in air and water using cantilever microresonators and a custom-built picobalance, to determine how photothermal efficiency changes along the propagation beam axis. It is identified that far out-of-band laser emission can lead to visual misidentification of the beam waist, resulting in a drop of photothermal efficiency of up to one order of magnitude. The measurements also unveil that the beam waist is not always the position of highest photothermal efficiency, and can reduce the efficiency up to 20% for silicon cantilevers with trapezoidal cross section.

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微谐振器光热激发的优化与误差
使用聚焦强度调制光(即光热激发)激发微谐振器的方法,因其即使在液体环境中也能准确激发微谐振器而不产生扭曲而备受关注,这也推动了原子力显微镜和相关技术的重要进步。尽管在涂层的开发方面取得了进展,但将光转换为机械运动的效率仍然很低,即使使用毫瓦级的光功率,也只能将共振器的运动限制在几十纳米的范围内。此外,对于光热效率如何取决于微谐振器沿光热束传播轴的相对位置的研究仍然很少,这妨碍了对光转化为机械运动的理解。在此,我们使用悬臂微谐振器和定制的皮平衡器在空气和水中进行了光热测量,以确定光热效率沿光束传播轴线的变化情况。结果表明,带外激光发射会导致光束腰的视觉识别错误,从而导致光热效率下降达一个数量级。测量还揭示出,光束腰并不总是光热效率最高的位置,对于梯形截面的硅悬臂,光热效率最高可降低 20%。
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