类抛物线形单孔悬挂芯光纤光镊设计与微粒操控

Design and particle manipulation of parabolic single-hole suspended-core fiber tweezers

  • 摘要: 为提高光镊系统中光纤波导耦合度与微通道集成度,实现对微粒的多样操控,提出了一种类抛物线形单孔悬挂芯光纤光镊结构,从双光束聚焦光场机制出发,分析并建立了光镊探针尖端横向和轴向光阱力数学模型,通过出射光场分布仿真模型的计算,探究了类抛物线形悬挂芯光纤中空孔直径、微粒尺寸与纤芯功率等参量对出射光场和光阱力的影响。结合悬挂芯光纤流道的气压控制,利用CO2激光熔融工艺制备了光纤光镊探针,建立了针对直径2、5 、10 μm的聚苯乙烯微粒操控实验。研究为单孔悬挂芯光纤应用于光纤光镊实现微粒操控乃至输运提供了技术基础,也为光纤光镊提高集成度与灵活性提供了新的思路。

     

    Abstract:
    Objective  Fiber optic tweezers have characteristics of compactness, high integration capability, and excellent portability, rendering them advantageous in applications such as chemical analyses, biosynthesis, and drug delivery systems. Single-hole suspension core fiber naturally integrates fiber waveguide and microfluidic channel, which can not only capture particles but also store, transport, analyze, and detect particles such as cells or drug molecules if applied in fiber optic tweezers. However, fiber-optic tweezers typically necessitate integration with microchannels or microfluidic technologies to perform multidimensional manipulations like transportation and sorting. The manufacture of microfluidic devices is complicated, and microfluidic devices and optical fibers as mutually independent devices with low system optical coupling efficiency and integration. Therefore, a simpler more efficient, and highly integrated method for particle or cell manipulation and transport is needed. For this reason, this thesis carries out research on fiber optic tweezer technology based on single-hole suspension core fibers to address the key issue of particle manipulation by suspension core fibers with hollow hole structures.
    Methods  The particle manipulation principle of single-hole-suspended-core fiber optical tweezers is analyzed, the analytical model of single-hole-suspended-core fiber optical tweezers is established from the mechanism of the double-beam focused light field, the analytical calculation method of the light trapping force is determined, and the characteristics of single-hole-suspended-core fibers with symmetric and off-core structures are analyzed at the same time. A parabolic-shaped single-hole-suspended-core fiber optical tweezers probe is designed, and its simulation model is used to calculate the optical field and optical trapping force, analyze the energy distribution and the characteristics of the optical trapping force, and investigate the specific effects of the hollow aperture, particle size, and core power on the optical trapping force manipulation performance. A parabolic-shaped single-hole-suspended-core fiber probe with a diameter of 9 μm at the tip of the probe was prepared by the CO2 laser melt-drawing cone method with pneumatic pressure control, and an experimental system was constructed to realize the manipulation experiments on polystyrene particles with diameters of 2 μm, 5 μm, and 10 μm.
    Results and Discussions  Simulations using Rsoft's Beamprop module were performed to analyze the optical field intensity distribution of single-hole-suspended-core fiber optical tweezers with different hollow apertures and core powers. The results show that increasing the hollow aperture enhances the light convergence effect (Fig.2). A model was established based on this simulation to investigate the effects of hollow aperture diameter, particle size, and fiber core power on the force on the particles. It was found that, the large aperture facilitates the provision of stable transverse and longitudinal capture points (Fig.4); Large-diameter particles facilitate longitudinal capture, while transverse capture requires appropriately sized particles (Fig.5); And the power of the suspension core has a significant effect on the transverse and longitudinal optical trapping forces, while the bias core has a lesser effect on the optical trapping forces (Fig.6). Finally, through the preparation and experimental verification of optical tweezers probes, it was confirmed that this parabolic single-aperture, dual-core, bias-suspended fiber optic tweezers could effectively manipulate particles with diameters of 2 μm, 5 μm, and 10 μm, and in particular showed the best performance for the manipulation of 5 μm particles (Fig.12).
    Conclusions  A parabolic single-aperture dual-core biased suspended fiber probe structure is proposed. The structural parameters of the probe are optimized through simulation analysis, which significantly affects the optical tweezer optical field and capture force, and the optical tweezer probe is experimentally prepared, thus verifying that the probe can flexibly manipulate particles with diameters of 2 μm, 5 μm, and 10 μm. In particular, it demonstrates an excellent capture and ejection ability for 5 μm particles. These optical tweezers probe enhances the integration potential of fiber optic tweezers and brings new perspectives on particle manipulation and sorting technology, which is of great scientific value.

     

/

返回文章
返回