Photoresist microbridge pattern optimization at 1μm using conventional photolithography technique

RSM 2013 IEEE Regional Symposium on Micro and Nanoelectronics Pub Date : 2013-09-01 DOI:10.1109/RSM.2013.6706462

B. S. Rao, M. Nurfaiz, U. Hashim

{"title":"Photoresist microbridge pattern optimization at 1μm using conventional photolithography technique","authors":"B. S. Rao, M. Nurfaiz, U. Hashim","doi":"10.1109/RSM.2013.6706462","DOIUrl":null,"url":null,"abstract":"One of the delicate processes in semiconductor microfabrication is the photolithography. It is the process that sets the design dimensions on various parts of the device. In order to complete this process, two requirements need to be satisfied. First is to create, the exact dimensions and pattern as established in design phase, which in other word can be referred as the resolution of the images on the wafer. The second is the correct placement of the device pattern on the wafer relative to the crystal orientation of the wafer substrate. This is called alignment or registration of patterns in correct position. This registration requirement is similar to the correct alignment of the different floors of a building. It is easy to visualize that misalignment of elevator shafts and stair wells would render the building useless. In a circuit, the effects of misaligned mask layers can cause the entire circuit to fail. In this paper we have reported a couple of results that leads to photoresist development and optimization technique as a standard manufacturing process to form 1μm microbridge for later process of size reduction to form nanogap. Therefore, at the final stage of fabrication, a nano-diagnostic biochip device is developed to use it as a biomolecule detection biosensor. The development of biosensors is still an open field and much remains to be done before many of these bioelectronic devices become commercialized. In this research, the key factors such as resist thickness, post-exposure bake (PEB) time and developer concentration are taken into account to study the optimum measurements and process. The thickness of resist will affect the resolution of image transferred and developing time. Both PEB and developer concentration also has the tendency to affect the device pattern and developing time. As the result, the photoresist thickness is optimized at 1500nm, the developer RD6 concentration diluted at 10:25 (DI water: RD6) and PEB time optimized at 65s.","PeriodicalId":346255,"journal":{"name":"RSM 2013 IEEE Regional Symposium on Micro and Nanoelectronics","volume":"47 1","pages":"0"},"PeriodicalIF":0.0000,"publicationDate":"2013-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"RSM 2013 IEEE Regional Symposium on Micro and Nanoelectronics","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1109/RSM.2013.6706462","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"","JCRName":"","Score":null,"Total":0}

引用次数: 1

Abstract

One of the delicate processes in semiconductor microfabrication is the photolithography. It is the process that sets the design dimensions on various parts of the device. In order to complete this process, two requirements need to be satisfied. First is to create, the exact dimensions and pattern as established in design phase, which in other word can be referred as the resolution of the images on the wafer. The second is the correct placement of the device pattern on the wafer relative to the crystal orientation of the wafer substrate. This is called alignment or registration of patterns in correct position. This registration requirement is similar to the correct alignment of the different floors of a building. It is easy to visualize that misalignment of elevator shafts and stair wells would render the building useless. In a circuit, the effects of misaligned mask layers can cause the entire circuit to fail. In this paper we have reported a couple of results that leads to photoresist development and optimization technique as a standard manufacturing process to form 1μm microbridge for later process of size reduction to form nanogap. Therefore, at the final stage of fabrication, a nano-diagnostic biochip device is developed to use it as a biomolecule detection biosensor. The development of biosensors is still an open field and much remains to be done before many of these bioelectronic devices become commercialized. In this research, the key factors such as resist thickness, post-exposure bake (PEB) time and developer concentration are taken into account to study the optimum measurements and process. The thickness of resist will affect the resolution of image transferred and developing time. Both PEB and developer concentration also has the tendency to affect the device pattern and developing time. As the result, the photoresist thickness is optimized at 1500nm, the developer RD6 concentration diluted at 10:25 (DI water: RD6) and PEB time optimized at 65s.

查看原文本刊更多论文

利用传统光刻技术优化1μm光刻胶微桥图案

在半导体微细制造中，光刻技术是一种精细的工艺。它是在设备的各个部件上设置设计尺寸的过程。为了完成这个过程，需要满足两个要求。首先是创建在设计阶段确定的精确尺寸和图案，换句话说，可以称为晶圆上图像的分辨率。第二是器件图案相对于晶圆衬底的晶体取向在晶圆上的正确放置。这称为模式在正确位置的对齐或注册。这一注册要求类似于建筑物不同楼层的正确对齐。很容易想象，电梯井和楼梯井的错位会使建筑毫无用处。在电路中，不对齐的掩模层的影响可能导致整个电路失效。在本文中，我们报告了一些结果，这些结果导致光刻胶的开发和优化技术成为形成1μm微桥的标准制造工艺，并在随后的尺寸减小过程中形成纳米间隙。因此，在制造的最后阶段，开发了一种纳米诊断生物芯片装置，将其用作生物分子检测生物传感器。生物传感器的发展仍然是一个开放的领域，在许多这些生物电子设备商业化之前还有很多工作要做。在本研究中，考虑了抗蚀剂厚度、曝光后烘烤(PEB)时间和显影剂浓度等关键因素，研究了最佳的测量和工艺。抗蚀剂的厚度会影响转印图像的分辨率和显影时间。PEB和显影剂浓度也有影响器件模式和显影时间的趋势。结果表明，光刻胶厚度优化为1500nm，显影剂RD6的稀释浓度为10:25 (DI水:RD6)， PEB时间优化为65s。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

RSM 2013 IEEE Regional Symposium on Micro and Nanoelectronics

自引率

0.00%

发文量