Abstract
Nowadays, optical tweezers have undergone explosive developments in accordance with a great progress of lasers. In the last decade, a breakthrough brought optical tweezers into the nano-world, overcoming the diffraction limit. This is called plasmonic optical tweezers (POT). POT are powerful tools used to manipulate nanomaterials. However, POT has several practical issues that need to be overcome. First, it is rather difficult to fabricate plasmonic nanogap structures regularly and rapidly at low cost. Second, in many cases, POT suffers from thermal effects (Marangoni convection and thermophoresis). Here, we propose an alternative approach using a nano-structured material that can enhance the optical force and be applied to optical tweezers. This material is metal-free black silicon (MFBS), the plasma etched nano-textured Si. We demonstrate that MFBS-based optical tweezers can efficiently manipulate small particles by trapping and binding. The advantages of MFBS-based optical tweezers are: (1) simple fabrication with high uniformity over wafer-sized areas, (2) free from thermal effects detrimental for trapping, (3) switchable trapping between one and two - dimensions, (4) tight trapping because of no detrimental thermal forces. This is the NON-PLASMONIC optical tweezers.
Highlights
There has been rapid development in plasmonics[1,2,3,4,5]
By overcoming the listed disadvantages of plasmonic optical tweezers (POT), we demonstrate that metal-free black silicon (MFBS)-based optical tweezers can be used to efficiently manipulate small particles with characteristic behaviours of one and two-dimentional (1D/2D) switchable trapping and manipulation
Before we discuss the trapping mechanism, we evaluated the trap stiffness on MFBS comparing with POT
Summary
The electric-field-enhancement effect of plasmon can be employed as an optical force to trap a small nano/micro-object with great efficiency. It is called plasmonic optical nano-tweezers (POT)[6,7,8,9]. The optical reflection of BS is only a few percent over visible and near-IR spectral ranges due to the refractive index gradient around pyramidal nano-spikes[28] Based on this unique non-reflecting BS platform, enhanced absorbance, BS has the function of light harvesting and was used to produce high efficiency >21% solar cells[30,31,32]. This technique has various advantages, and is expected to open a new chapter in advanced optical trapping
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