Investigation of the Transition from Local Anodic Oxidation to Electrical Breakdown During Nanoscale Atomic Force Microscopy Electric Lithography of Highly Oriented Pyrolytic Graphite

Yang, Yunhua; Jun, Lin

doi:10.1017/s1431927616000027

Cited by 4 publications

(3 citation statements)

References 25 publications

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“…Electrochemical etching using AFM tip over HOPG surface to obtain atomic-scale machining has been reported in earlier studies [76,131,132]. Since only a few works have been performed on AFM machining over HOPG in recent years, we have mentioned some of the earlier works before 2010.…”

Section: Hopg: Highly Oriented Pyrolytic Graphitementioning

confidence: 98%

“…This includes the effects of machining performance on fabrication mechanism and transition from LAO to electrical breakdown during lithography. Yang and Lin [131] performed such an experiment to understand the machining performance and the transitions like the above mentioned on HOPG. They have used a Si probe coated with conductive TiN films.…”

Section: Hopg: Highly Oriented Pyrolytic Graphitementioning

confidence: 99%

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Atomic and Close-to-Atomic Scale Manufacturing: A Review on Atomic Layer Removal Methods Using Atomic Force Microscopy

Mathew

Rodriguez

2020

Nanomanuf Metrol

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Manufacturing at the atomic scale is the next generation of the industrial revolution. Atomic and close-to-atomic scale manufacturing (ACSM) helps to achieve this. Atomic force microscopy (AFM) is a promising method for this purpose since an instrument to machine at this small scale has not yet been developed. As the need for increasing the number of electronic components inside an integrated circuit chip is emerging in the present-day scenario, methods should be adopted to reduce the size of connections inside the chip. This can be achieved using molecules. However, connecting molecules with the electrodes and then to the external world is challenging. Foundations must be laid to make this possible for the future. Atomic layer removal, down to one atom, can be employed for this purpose. Presently, theoretical works are being performed extensively to study the interactions happening at the molecule–electrode junction, and how electronic transport is affected by the functionality and robustness of the system. These theoretical studies can be verified experimentally only if nano electrodes are fabricated. Silicon is widely used in the semiconductor industry to fabricate electronic components. Likewise, carbon-based materials such as highly oriented pyrolytic graphite, gold, and silicon carbide find applications in the electronic device manufacturing sector. Hence, ACSM of these materials should be developed intensively. This paper presents a review on the state-of-the-art research performed on material removal at the atomic scale by electrochemical and mechanical methods of the mentioned materials using AFM and provides a roadmap to achieve effective mass production of these devices.

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Section: Hopg: Highly Oriented Pyrolytic Graphitementioning

confidence: 98%

Section: Hopg: Highly Oriented Pyrolytic Graphitementioning

confidence: 99%

Atomic and Close-to-Atomic Scale Manufacturing: A Review on Atomic Layer Removal Methods Using Atomic Force Microscopy

Mathew

Rodriguez

2020

Nanomanuf Metrol

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“…别进行结构和成分分析，发现随着温度的升高，其成分和物相均发生了改变 [14] ；或者利用(扫描电镜)SEM 观察材料的分层结构完整或者塌陷 [15] ，从而来判断结构的稳定性。上述的这些方法操作过程繁琐，不利于快速便捷检测。所以，本文提出一种利用原子力显微镜(Atomic Force Microscope，AFM)来快速分析二维材料稳定性的方法。原子力显微镜是由扫描隧道显微镜(Scanning Tunneling Microscope，STM)发展而来，但与 STM 检测隧穿电流不同的是，AFM 的测试是基于探针与样品之间的范德华作用力，因此，不受样品导电性质影响，可用于绝缘体、半导体、导体的研究 [16][17][18] 。其成像原理是当探针在样品表面进行扫描时，探针与样品间的作用力会使探针悬臂发生偏转，光电探测器通过收集悬臂梁的弯曲度或偏转度，经计算机处理，可生成表面形貌的图像。通常而言，AFM 的成像模式包括接触模式(Contact Mode) [19] [20][21][22] [23,24] 1 实验材料与方法本实验所运用的石墨烯是通过还原氧化石墨的方法获得的：首先采用 Hummer's 方法 [25] 制备出氧化石墨烯产物，所得产物用稀盐酸洗涤后，放置在 80 ℃的真空干燥箱中真空干燥 72 h。然后，取少量干燥的氧 [26,27] 。二维材料 V2C MXene 的制备 [5] ：通过从 V2AlC 粉末中蚀刻 Al 制成的。其中，V2AlC 是将钒粉，铝粉 [29] ，从图 3(l)可知本实验中二维材料 V2C MXene 的高度约为 4.5 nm 左右，说明并非是单层结 [30] 。其次，由于氢氟酸的强腐蚀性，与氢氟酸直接接触的表面容易产生缺陷，如原子空位 [31] 。因此，由于上述两种情况的存在，导致材料表面结…”

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Comparison of Structure Stability of Graphene and Mxene by Peak Force Tapping Mode of Atomic Force Microscope

Shen¹

2021

Preprint

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In this paper, the structural stability of graphene and Mexene was compared by peak force tapping mode of AFM. When in-situ scanning of two-dimensional material of reduced graphene oxide (rGO), the morphology of rGO did not change with time, which indicated that peak force tapping mode had no damage effect on the stable structure surface; while when in-situ scanning of two-dimensional material V2C, nano-etching occurred on the surface of V2C, and the morphology surface area decreased with scanning time. The data processing software was used to analyze the area change and calculate the nano etching rate. It was found that the average nano-etching rate increased with the increase of the peak force, and the etching rate in the atmospheric environment was higher than that in the glove box (Ar atmosphere, the H2O and O2 content was less than 1 ppm), which indicated that the moisture in the atmosphere had an impact on the stability of the material and would accelerate the nano-etching. This study shows that the peak force tapping mode of AFM can be used to qualitatively characterize the stability of two-dimensional materials

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Fabrication of nanoscale to microscale 2.5D square patterns on metallic films by the coupling AFM lithography

Yang

Zhao

2019

Journal of Manufacturing Processes

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Investigation of the Transition from Local Anodic Oxidation to Electrical Breakdown During Nanoscale Atomic Force Microscopy Electric Lithography of Highly Oriented Pyrolytic Graphite

Cited by 4 publications

References 25 publications

Atomic and Close-to-Atomic Scale Manufacturing: A Review on Atomic Layer Removal Methods Using Atomic Force Microscopy

Atomic and Close-to-Atomic Scale Manufacturing: A Review on Atomic Layer Removal Methods Using Atomic Force Microscopy

Comparison of Structure Stability of Graphene and Mxene by Peak Force Tapping Mode of Atomic Force Microscope

Fabrication of nanoscale to microscale 2.5D square patterns on metallic films by the coupling AFM lithography

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