Environmental-friendly microlens array for field curvature correction

Fig (a) Working principle of the microlens array, (b) scanning electron microscope (SEM) characterization, (c) microscope photographs, (d) dark field focus image.

Field curvature is a widespread matter in large field optical imaging systems, which means even if you are imaging a planar object, you can only achieve high sharpness at the focus position, and the image in the edge area may become blur. However, the existing optical systems and imaging components are mostly planar designs, so it is particularly important to eliminate field curvature aberrations.

As a natural biomacromolecular material, the protein materials have the advantages of wide source, renewable, biocompatible, non-polluting, and absorbable degradation. In recent years, with the help of growing maturity of micro-nano processing technology, many special functions of protein-based micro-nano structures, including micro-devices and even integrated systems have been successfully realized.

Based on hereinbefore background, the researchers from the group of Prof. Hong-Bo Sun (the Key Laboratory of Integrated Optoelectronics of Jilin University) demonstrated a three-dimensional microlens array with different curvature unit lenses (MLADC) based on bovine serum albumin (BSA) fabricated by femtosecond laser two-photon polymerization direct writing (FsDLW). The MLADC possesses unique and characteristic optical performance, as the curvatures of unit lenses are different along with their different positions, which will play a significant role in optimizing optical system structure and reducing optical elements, especially in field curvature correction. In addition, due to the unique advantages of FsDLW, such as non-contact and low thermal damage, the biological activity of the protein is partially retained. Therefore, it is easy to achieve a fine adjustment of the focal plane by utilizing the equilibrium swelling of the protein hydrogel in the solution. These results are reported in Chinese Optics Letters Vol. 17, No. 6 2019 (Zhishan Hou, et al., Tunable protein microlens array).

"These results show the application prospects of protein-based materials in new biophotonics and biomedical fields, indicating the great potential of femtosecond laser direct writing technology in building "smart" integrated photonic micro/nano-biological systems," said Dr. Zhi-Shan Hou from this group.

Their further work will focus on the dual controllable design of femtosecond laser direct writing in device geometry and material functional properties, and give the device novel and diverse features and functions by fully exploiting and utilizing the intrinsic properties of proteins.


图 (a)微透镜阵列工作原理,(b)器件扫描电镜(SEM)表征,(c)器件显微镜照片,(d)器件暗场成像照片。



基于以上背景,来自吉林大学集成光电子重点实验室的杨罕教授课题组提出了利用飞秒激光双光子聚合直写制备基于牛血清白蛋白的三维场曲矫正微透镜组,它通过排列焦距不同的多组微透镜阵列,实现了对弯曲像平面的平面矫正。另外,得益于飞秒激光超快脉冲非接触、低附带热损伤的独特优势,使得蛋白质的生物活性得以部分保留。因此,可以通过利用蛋白质水凝胶自身在溶液中的平衡溶胀,实现透镜组矫正焦平面的再度微调。该成果发表在Chinese Optics Letters 2019年第17卷第6期上(Zhishan Hou, et al., Tunable protein microlens array)。