Mesoscale-object handling by temperature modulation of surface stresses

E. Vela, M. Hafez, S. Régnier, S. Bouchigny
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Abstract

In this work, we present the non-contact manipulation of mesoscale random-shaped, large and heavy objects immersed in thin liquid water (< 0.8 mm). The manipulation principle used is the modulation of surface tension by infra red (IR) laser (1480 nm) absorption. Laser absorption generates surface-tension-driven flows. At the water-air interface, the flows go away from the laser beam (colder region), and at the bottom they go toward the laser (recirculation cell). We use these flows to drag immersed objects toward the laser focus. With laser scanning, several kinds of fluidic patterns can be obtained for specific handlings such as trapping, mixing and sorting of microcomponents. High speed flows can be reached; therefore high velocity particle manipulation can be achieved (several mm/s). Experimental measurements reported a velocity of about 5 mm/s for a spherical glass bead of 90 ¿m in diameter. With these flows, nN range forces are obtained. These forces are about 1000 times larger than forces generated with optical tweezers.
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通过表面应力的温度调制处理中尺度物体
在这项工作中,我们提出了浸泡在薄液态水(< 0.8 mm)中的中尺度随机形状,大型和重型物体的非接触操作。所使用的操作原理是通过红外(IR)激光(1480 nm)吸收调制表面张力。激光吸收产生表面张力驱动流。在水气界面处,气流远离激光束(较冷的区域),而在底部流向激光(再循环单元)。我们利用这些气流将浸入的物体拖向激光焦点。通过激光扫描,可以获得几种流体模式,用于特定的处理,如捕获、混合和分选微组分。可达到高速流动;因此,可以实现高速粒子操作(几毫米/秒)。实验测量报告了直径为90微米的球形玻璃珠的速度约为5毫米/秒。利用这些流,得到了n个范围力。这些力比光镊产生的力大1000倍。
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