Fabrication of Se-Fe2O3-based Schottky Diode Using Cantilever-based Ag-contact Printing Technology : Topic: NS/NC - Non-silicon and Non-CMOS

2022 33rd Annual SEMI Advanced Semiconductor Manufacturing Conference (ASMC) Pub Date : 2022-05-02 DOI:10.1109/asmc54647.2022.9792480

Joshua Roy Palathinkal, Sumit Majumder, Thomas T. Daniel, V. Yadav, R. P. Palathinkal

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Abstract

The fabrication of a sub-10 μm Se-Fe2O3 channel Schottky diode built using cantilever-based Ag-contact printing technology is discussed in this work. There are two phases to the fabrication process. In the first phase, the Ag electrodes are produced using a state-of-the-art micro-girder (μG) cantilever-based in-house printing system. The second phase involves dropcasting the dispersion of leaf-structured Se-Fe2O3 in deionized (DI) water between the printed electrodes. The printed device’s electrical response is observed to be similar to that of a Schottky diode. An analytical model based on the thermionic emission theory was used to verify these features with the acquired experimental results. The ideality factor of the device is extracted as 3.44. At room temperature, the device exhibits a barrier height of 0.72 eV and series resistance of 159 kΩ. As the novel μG printing technology is in its early stages of development, the results presented in this work are preliminary in nature and work on further optimization is being carried out.

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利用悬臂式银触点印刷技术制备se - fe2o3基肖特基二极管:主题:NS/NC -非硅和非cmos

本文讨论了采用悬臂式银接触印刷技术制备低于10 μm Se-Fe2O3通道肖特基二极管的方法。制造过程有两个阶段。在第一阶段，使用最先进的微梁(μG)悬臂式内部打印系统生产银电极。第二阶段涉及在印刷电极之间的去离子水中投射叶状结构的Se-Fe2O3分散体。观察到印刷器件的电响应与肖特基二极管相似。利用基于热离子发射理论的解析模型与实验结果验证了这些特征。提取出该装置的理想系数为3.44。在室温下，该器件的势垒高度为0.72 eV，串联电阻为159 kΩ。由于这种新型的μG打印技术还处于发展的早期阶段，本工作的结果是初步的，进一步的优化工作正在进行中。

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2022 33rd Annual SEMI Advanced Semiconductor Manufacturing Conference (ASMC)

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