Your search keyword '"chemical lift-off lithography"' showing total 3 results

1. Gap-directed chemical lift-off lithographic nanoarchitectonics for arbitrary sub-micrometer patterning

Author

Chang-Ming Wang, Hong-Sheng Chan, Chia-Li Liao, Che-Wei Chang, and Wei-Ssu Liao

Subjects

chemical lift-off lithography, gap, self-assembled monolayer, sub-micrometer, surface patterning, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

We introduce a unique soft lithographic operation that exploits stamp roof collapse-induced gaps to selectively remove an alkanethiol self-assembled monolayer (SAM) on Au to generate surface patterns that are orders of magnitude smaller than structures on the original elastomer stamp. The smallest achieved feature dimension is 5 nm using a micrometer-scale structured stamp in a chemical lift-off lithography (CLL) process. Molecular patterns retained in the gaps between stamp features and their circumscribed or inscribed circles follow mathematical predictions, and their sizes can be tuned by altering the stamp structure dimensions, including height, pitch, and shape. These generated surface molecular patterns can function as biorecognition arrays or be transferred to the underneath Au layer for metallic structure creation. By combining CLL process with this gap phenomenon, soft material properties that are previously thought as demerits can be used to achieve sub-10 nm features in a straightforward sketch.

Published

2023

2. Wafer-scale bioactive substrate patterning by chemical lift-off lithography

Author

Chong-You Chen, Chang-Ming Wang, Hsiang-Hua Li, Hong-Hseng Chan, and Wei-Ssu Liao

Subjects

bioactive substrate, chemical lift-off lithography, patterning, self-assembled monolayer, Technology, Chemical technology, TP1-1185, Science, Physics, QC1-999

Abstract

The creation of bioactive substrates requires an appropriate interface molecular environment control and adequate biological species recognition with minimum nonspecific attachment. Herein, a straightforward approach utilizing chemical lift-off lithography to create a diluted self-assembled monolayer matrix for anchoring diverse biological probes is introduced. The strategy encompasses convenient operation, well-tunable pattern feature and size, large-area fabrication, high resolution and fidelity control, and the ability to functionalize versatile bioarrays. With the interface-contact-induced reaction, a preformed alkanethiol self-assembled monolayer on a Au surface is ruptured and a unique defect-rich diluted matrix is created. This post lift-off region is found to be suitable for insertion of a variety of biological probes, which allows for the creation of different types of bioactive substrates. Depending on the modifications to the experimental conditions, the processes of direct probe insertion, molecular structure change-required recognition, and bulky biological species binding are all accomplished with minimum nonspecific adhesion. Furthermore, multiplexed arrays via the integration of microfluidics are also achieved, which enables diverse applications of as-prepared substrates. By embracing the properties of well-tunable pattern feature dimension and geometry, great local molecular environment control, and wafer-scale fabrication characteristics, this chemical lift-off process has advanced conventional bioactive substrate fabrication into a more convenient route.

Published

2018

3. Large Area Nanoparticle Alignment by Chemical Lift-Off Lithography.

Author

Chen, Chong-You, Chang, Chia-Hsuan, Wang, Chang-Ming, Li, Yi-Jing, Chu, Hsiao-Yuan, Chan, Hong-Hseng, Huang, Yu-Wei, and Liao, Wei-Ssu

Subjects

*NANOPARTICLES, *ENERGY harvesting

Abstract

Nanoparticle alignment on the substrate attracts considerable attention due to its wide application in different fields, such as mechanical control, small size electronics, bio/chemical sensing, molecular manipulation, and energy harvesting. However, precise nanoparticle positioning and deposition control with high fidelity are still challenging. Herein, a straightforward strategy for high quality nanoparticle-alignment by chemical lift-off lithography (CLL) is demonstrated. This technique creates high resolution self-assembled monolayer (SAM) chemical patterns on gold substrates, enabling nanoparticle-selective deposition and precise alignment. The fabricated nanoparticle arrangement geometries and dimensions are well-controllable in a large area. With proper nanoparticle surface functionality control and adequate substrate molecular manipulation, well-defined nanoparticle arrays with single-particle-wide alignment resolution are achieved. [ABSTRACT FROM AUTHOR]

Published

2018