Controlled Light-Driven Levitation of Macroscopic Plates

Proceedings of Micromachines 2021 — 1st International Conference on Micromachines and Applications (ICMA2021) Pub Date : 2021-04-14 DOI:10.3390/micromachines2021-09569

Mohsen Azadi, G. Popov, Zhipeng Lu, Andy G. Eskenazi, A. Bang, M. Campbell, Howard H. Hu, I. Bargatin

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Abstract

Photophoretic or light-driven levitation has been studied extensively in the context of the motion of illuminated micron-sized particles, such as dust grains in the atmosphere under sunlight [1,2], and in relation to Crooks radiometers [3]. When heated by incident light, a micron-sized particle experiences a temperature gradient that in turn results in uneven gas-surface interactions and a net propulsive force [4]. Though thoroughly investigated for micron-sized particles, this phenomenon has rarely been studied to controllably levitate macroscopic objects. We report light-driven levitation of 0.5-um thick mylar samples that have been modified by depositing a 300-nm-thick layer of carbon nanotubes (CNTs) on a single side. The CNT layer serves three key purposes: 1) It acts as a lightweight light absorber, absorbing ~ 90% of the incident light and elevating the temperature of the sample. 2) It increases the structural rigidity of the mylar film, allowing cm-scale discs with submicron thicknesses to hold their shape. 3) It creates a structured porous surface that traps impinging gas molecules, which results in an accommodation coefficient difference between the top and bottom surfaces for gas-surface interactions. Air molecules that rebound from the CNT-coated side have on average higher velocities than those departing from the opposing uncoated mylar surface. We show that the net force thus created can be used to levitate the mylar films. Moreover, we will demonstrate our ability to manipulate a light field in order to control the flight of levitating samples for extended periods of time. References: Jovanovic, O. Photophoresis—Light induced motion of particles suspended in gas. Journal of quantitative spectroscopy & radiative transfer 110, 889–901, (2009) Horvath, Photophoresis – a forgotten force ??, KONA powder and particle journal, 31, 181–199 (2014) Ketsdever, N. Gimelshein, S. Gimelshein, and N. Selden, “Radiometric phenomena: From the 19th to the 21st century”, Vacuum 86, 1644-1662 (2012). Loesche, G. Wurm, T. Jankowski, M. Kuepper, Photophoresis on particles hotter/colder than the ambient gas in the free molecular flow. J. Aerosol Sci, 97, 22–33 (2016)

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控制光驱动悬浮宏观板

光致或光驱动悬浮已经在微米级粒子的运动背景下进行了广泛的研究，如大气中的尘埃颗粒在阳光下的运动[1,2]，并与克鲁克斯辐射计[3]有关。当被入射光加热时，微米大小的粒子经历温度梯度，从而导致不均匀的气体表面相互作用和净推进力[4]。虽然对微米大小的粒子进行了彻底的研究，但这种现象很少被研究用于控制悬浮宏观物体。我们报告了0.5 um厚的聚酯膜样品的光驱动悬浮，这些样品通过在单面沉积300 nm厚的碳纳米管(CNTs)层来修饰。碳纳米管层有三个主要目的:1)它作为轻质光吸收剂，吸收约90%的入射光并提高样品的温度。2)它增加了聚酯薄膜的结构刚性，使厘米级的圆盘具有亚微米厚度保持其形状。3)它创造了一个结构化的多孔表面，可以捕获撞击的气体分子，这导致气体表面相互作用的上下表面之间的调节系数不同。空气分子从碳纳米管涂层的一面反弹的平均速度比从相反的未涂覆的聚酯膜表面反弹的速度要高。我们表明，由此产生的合力可以用来悬浮聚酯薄膜。此外，我们将展示我们操纵光场的能力，以控制悬浮样品的飞行时间延长。参考文献:Jovanovic, O.光致吸附——悬浮在气体中的粒子的光诱导运动。定量光谱学与辐射传递学报，2009,889-901，(2009)陈晓明，陈晓明，陈晓明，“辐射测量技术的研究进展”，科学通报，2012，(2):1 - 2。卢思哲，杨可夫斯基，M. Kuepper，自由分子流中比环境气体更热/更冷粒子的光致电泳。气溶胶科学，97,22-33 (2016)

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Proceedings of Micromachines 2021 — 1st International Conference on Micromachines and Applications (ICMA2021)

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