Electrochemical Lensing for High Resolution Nanostructure Synthesis

arXiv - PHYS - Atomic and Molecular Clusters Pub Date : 2024-03-09 DOI:arxiv-2403.06010

Auwais Ahmed, Peter A. Kottke, Andrei G. Fedorov

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Abstract

The advancement of liquid phase electron beam induced deposition has enabled an effective direct-write approach for functional nanostructure synthesis with the possibility of three-dimensional control of morphology. For formation of a metallic solid phase, the process employs ambient temperature, beam-guided, electrochemical reduction of precursor cations resulting in rapid formation of structures, but with challenges for retention of resolution achievable via slower electron beam approaches. The possibility of spatial control of redox pathways via the use of water-ammonia solvents has opened new avenues for improved nanostructure resolution without sacrificing the growth rate. We find that ammonia concentration locally modulates reaction kinetics, altering the balance between reducing and oxidizing species, leading to distinct deposition outcomes. The key effect is an 'electrochemical lensing', achieved at an optimum ammonia concentration, in which a tightly confined and highly reducing environment is created locally to enable high resolution, rapid beam-directed nanostructure growth. We demonstrate this unique approach to high resolution synthesis through a combination of analysis and experiment.

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电化学透镜用于高分辨率纳米结构合成

液相电子束诱导沉积技术的发展为功能性纳米结构的合成提供了一种有效的直接写入方法，并可对形态进行三维控制。在金属固相的形成过程中，采用环境温度、电子束引导、电化学还原前体阳离子的方法，可快速形成结构，但在保持较低电子束方法所能达到的分辨率方面存在挑战。通过使用水-氨溶剂对再氧化途径进行空间控制的可能性为在不牺牲生长速度的情况下提高纳米结构的分辨率开辟了新的途径。我们发现氨的浓度会局部调节反应动力学，改变还原物种和氧化物种之间的平衡，从而导致不同的沉积结果。其关键效果是在最佳氨浓度下实现的 "电化学透镜效应"，在这种效应下，会在局部形成一个紧密封闭的高还原性环境，从而实现高分辨率、快速的光束导向纳米结构生长。我们通过分析和实验相结合的方法展示了这种独特的高分辨率合成方法。

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arXiv - PHYS - Atomic and Molecular Clusters

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