School of Chemical and Biomolecular Sciences, Southern Illinois University, Carbondale, Illinois 62901, United States.
School of Physics and Applied Physics, Southern Illinois University, Carbondale, Illinois 62901, United States.
Langmuir. 2022 Oct 18;38(41):12630-12643. doi: 10.1021/acs.langmuir.2c02096. Epub 2022 Oct 6.
Simultaneous writing and erasing of two and three molecules in one single step at the microscale using Polymeric Lithography Editor (PLE) probes is demonstrated. Simultaneous writing and erasing of three molecules was accomplished by rastering a nanoporous probe that was loaded with rhodamine B and fluorescein over a quinine-coated glass substrate. The solvated quinine molecules were erased and transported into the probe matrix, whereas both rhodamine and fluorescein molecules were simultaneously deposited and aligned with the path of the erased quinine on the substrate. The simultaneous writing and erasing of molecules is referred to as PLiSED. The writing and erasing speed can be easily tuned by adjusting the probe speed to as large as 10,000 μm/s. The microscale patterns on the orders of square millimeter area were fabricated by erasing fluorescein with an efficiency (η) > 95% while simultaneously depositing rhodamine molecules at the erased spots. The roles of the probe porosity, transport medium, and kinetics of solvation for editing were also investigated─the presence of a transport medium at the probe-substrate interface is required for the transport of the molecules into and out of the probe. The physical and mechanical properties of the polymeric probes influenced molecular editing. Young's modulus values of the hydrated hydrogels composed of varying monomer/cross-linker ratios were estimated using atomic force microscopy. Probes with the highest observed erasing capacity were used for further experiments to investigate the effects of relative humidity and erasing time on editing. Careful control over experimental conditions provided high-quality editing of microscale patterns at high editing speed. Combining erasing and deposition of multiple molecules in one single step offers a unique opportunity to significantly improve the efficiency and the accuracy of lithographic editing at the microscale. PLiSED enables rapid on-site lithographic rectification and has considerable application values in high-quality lithography and solid surface modification.
使用高分子光刻编辑器 (PLE) 探针在微尺度上一步实现两个和三个分子的同时写入和擦除。通过在涂有奎宁的玻璃基底上对负载有罗丹明 B 和荧光素的纳米多孔探针进行光栅扫描,实现了三个分子的同时写入和擦除。被溶剂化的奎宁分子被擦除并输送到探针基质中,而罗丹明和荧光素分子则同时沉积并沿着基质上被擦除的奎宁路径排列。这种分子的同时写入和擦除被称为 PLiSED。通过将探针速度调整到高达 10000μm/s,很容易调整写入和擦除速度。通过用效率 (η) > 95%的荧光素擦除来制造面积为平方毫米量级的微图案,同时在擦除的斑点处沉积罗丹明分子。还研究了探针孔隙率、传输介质和溶剂化动力学在编辑中的作用——在探针-基底界面存在传输介质是将分子传输进出探针所必需的。聚合物探针的物理和机械性能影响分子编辑。使用原子力显微镜估计了由不同单体/交联剂比组成的水合水凝胶的杨氏模量值。使用观察到的最高擦除能力的探针进行进一步的实验,以研究相对湿度和擦除时间对编辑的影响。仔细控制实验条件可在高速编辑下实现高质量的微图案编辑。在单个步骤中同时擦除和沉积多个分子提供了一个独特的机会,可以显著提高微尺度下光刻编辑的效率和准确性。PLiSED 实现了快速现场光刻校正,在高质量光刻和固体表面改性方面具有重要的应用价值。
