Ni Haibin, Yuan Guanghui, Sun Liangdong, Chang Ning, Zhang Di, Chen Ruipeng, Jiang Liyong, Chen Hongyuan, Gu Zhongze, Zhao Xiangwei
State Key Laboratory of Bioelectronics, School of Biological Science and Medical Engineering, National Demonstration Center for Experimental Biomedical Engineering Education, Southeast University Nanjing 210096 China
Jiangsu Key Laboratory of Meteorological Observation and Information Processing, Nanjing University of Information Science and Technology Nanjing 210044 China.
RSC Adv. 2018 Jun 4;8(36):20117-20123. doi: 10.1039/c8ra02644k. eCollection 2018 May 30.
In this study, direct laser writing (DLW) lithography is employed to fabricate a large-scale and high-numerical-aperture super-oscillatory lens (SOL), which is capable of achieving a sub-Abbe-Rayleigh diffraction limit focus in the optical far-field region by delicate interference. Large-diameter (600 μm), amplitude-modulated and phase-type SOLs with the smallest annular ring width of 1 μm are fabricated, and they have high quality. The dependence of DLW printing on the fabrication parameters including substrate materials, laser power, and scanning speed is well investigated. A standard procedure to manufacture high-quality binary amplitude SOLs is presented, which avoids direct printing patterns on metal films and reduces the surface roughness dramatically. Random displacements between squares constituting SOLs are discussed, and their influence on the focusing performance is studied by both numerical simulations and experiments. The optical performances of the SOLs fabricated by the DLW method are experimentally characterized, and a needle-like focus with a spot size of 0.42 and a depth of focus of ∼6 μm are confirmed at a working distance of 100 μm for = 633 nm, thus giving an effective numerical aperture as high as 1.19 in air. As a complementary sub-micrometer fabrication method between traditional lithography and nanofabrication method, DLW is proved to be a promising approach to manufacture SOLs, presenting advantages of relatively high speed, low equipment volume, less complexity and sub-micrometer lateral resolution. Such SOLs can be very useful in high resolution bio-imaging on rough surfaces and in the related research fields.
在本研究中,采用直接激光写入(DLW)光刻技术制造了一种大规模、高数值孔径的超振荡透镜(SOL),该透镜能够通过精细干涉在光学远场区域实现亚阿贝 - 瑞利衍射极限聚焦。制造出了大直径(600μm)、振幅调制且相位型的SOL,其最小环形环宽度为1μm,且质量很高。深入研究了DLW打印对包括衬底材料、激光功率和扫描速度在内的制造参数的依赖性。提出了一种制造高质量二元振幅SOL的标准程序,该程序避免了在金属膜上直接打印图案,并显著降低了表面粗糙度。讨论了构成SOL的正方形之间的随机位移,并通过数值模拟和实验研究了它们对聚焦性能的影响。通过实验对采用DLW方法制造的SOL的光学性能进行了表征,对于λ = 633nm,在100μm的工作距离处确认了光斑尺寸为0.42且焦深约为6μm的针状焦点,从而在空气中给出了高达1.19的有效数值孔径。作为传统光刻和纳米制造方法之间的一种互补亚微米制造方法,DLW被证明是制造SOL的一种有前途的方法,具有相对较高的速度、较小的设备体积、较低的复杂性和亚微米横向分辨率等优点。这种SOL在粗糙表面的高分辨率生物成像及相关研究领域中可能非常有用。
