Abstract
Atomic force microscopy (AFM)-based electrochemical etching of a highly oriented pyrolytic graphite (HOPG) surface is studied toward the single-atomic-layer lithography of intricate patterns. Electrochemical etching is performed in the water meniscus formed between the AFM tip apex and HOPG surface due to a capillary effect under controlled high relative humidity (~ 75%) at otherwise ambient conditions. The conditions to etch nano-holes, nano-lines, and other intricate patterns are investigated. The electrochemical reactions of HOPG etching should not generate debris due to the conversion of graphite to gaseous CO and CO2 based on etching reactions. However, debris is observed on the etched HOPG surface, and incomplete gasification of carbon occurs during the etching process, resulting in the generation of solid intermediates. Moreover, the applied potential is of critical importance for precise etching, and the precision is also significantly influenced by the AFM tip wear. This study shows that the AFM-based electrochemical etching has the potential to remove the material in a single-atomic-layer precision. This result is likely because the etching process is based on anodic dissolution, resulting in the material removal atom by atom.
Highlights
The etching voltage could be applied to the Atomic force microscopy (AFM) tip and highly oriented pyrolytic graphite (HOPG) workpiece using AFM controller electronics with a voltage range of − 10 to 10
This study focuses on the single-atomic-layer lithography on the HOPG surface using the AFM-based electrochemical etching technique
The experimental results show that single-atomic-layer precision can be achieved on the HOPG surface for different intricate patterns
Summary
Nanomanufacturing involves scaled-up, reliable, and costeffective manufacturing of nanoscale materials, structures, devices, and systems [1] It leads to the production of improved materials and new products, and manufactured structures with unique properties in the nanoscale are capable of enabling quantum leaps and improvement in highperformance technologies, from new sensors, high-density data storage, and drug delivery to high-strength materials and energy-efficient solar cells [2, 3]. HOPG is typically obtained via the graphitization heat treatment of carbon or chemical vapor deposition under pressure and high temperatures It is usually used in nanolithography and obtaining graphene due to the ease of preparation of atomically flat surfaces and layered structures. Nano-holes and nano-lines were etched to investigate
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
