Affiliation:
1. School of Biomedical Engineering Faculty of Engineering and IT University of Sydney Sydney NSW 2006 Australia
2. The University of Sydney Nano Institute University of Sydney Sydney NSW 2006 Australia
3. Institute of Photonics and Optical Science (IPOS) School of Physics Faculty of Science University of Sydney Sydney NSW 2006 Australia
4. The Institute of Optics University of Rochester Rochester NY 14627 USA
5. Department of Physics University of Basel Basel 4056 Switzerland
Abstract
AbstractThe 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.