Roll-to-roll production of a microfluidic platform and its functionalization by means of digital printing technologies for gas and fluid sensors (Conference Presentation)

Organic and Hybrid Sensors and Bioelectronics XI Pub Date : 2018-09-18 DOI:10.1117/12.2321306

C. Eschenbaum, A. Habermehl, Robert Huber, U. Lemmer, Noah Strobel, A. Mertens, G. Hernández-Sosa

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引用次数: 1

Abstract

The individualized functionalization of mass-produced microstructures is still challenging for the process technology. Here, a rroll-to-roll based process hot embossing is presented for the production of microfluidic structures by means of hot embossing is presented. The resulting microfluidic channels are functionalized modified with different materials. Thereby, digital printing technologies such as aAerosoljet or inkjet are used. This approach allows for mass production of microfluidic channels and their the individualized individual functionalizationfunctionalization of mass produced microfluidic channels. The encapsulation of the channels also takes placeis realized in an R2R-based thermal bonding process without adding any solvent or adhesive. Taking account ofUsing this approach, several sensor systems for gas and / or fluid detection could be demonstrated. Surface -eEnhanced Raman Scattering scattering (SERS) with amplification enhancement factors of up to 107 [1] is demonstrated by printing gold nanoparticles into the microfluidic channel. We evaluate the printed SERS structures using solutions of rhodamine 6G and adenosine as exemplary analytes. Furthermore, these channels could be functionalized with different fluorescent organic semiconductors. Their fluorescence intensity is quenched in the presence of a nitroaromatic compounds. By using different materials simultaneously, we are able to measure a fingerprint like pattern of different analytes, which we evaluated by means ofusing pattern recognition algorithms. This method can be used both in the gas phase (electronic nose) and in fluids (electronic tongue) for the detection of nitroaromatic compounds [2,3]. With the opto-electronic nose, we were able to reach detections limits below 1ppb. [1] A. Habermehl et al, Sensors 17, 2401 (2017). [2] N. Bolse et al, Flexible and Printed Electronics 2, 024001 (2017) [3] N. Bolse et al, ACS Omega 2 (10), 6500-6505 (2017)

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微流控平台的卷对卷生产及其应用于气体和流体传感器的数字印刷技术的功能化(会议报告)

批量生产的微结构的个性化功能化对工艺技术来说仍然是一个挑战。本文提出了一种基于卷对卷热压印的微流控结构生产方法。所得到的微流控通道被不同的材料功能化修饰。因此，数字印刷技术，如aAerosoljet或喷墨被使用。这种方法允许大规模生产微流控通道，以及大规模生产微流控通道的个性化功能化。通道的封装也可以在基于r2r的热粘合过程中实现，而无需添加任何溶剂或粘合剂。考虑到使用这种方法，可以演示几种用于气体和/或流体检测的传感器系统。通过将金纳米颗粒打印到微流体通道中，证明了表面增强拉曼散射(SERS)的放大增强因子高达107[1]。我们使用罗丹明6G和腺苷溶液作为示例分析物来评估打印的SERS结构。此外，这些通道可以用不同的荧光有机半导体功能化。它们的荧光强度在硝基芳香族化合物的存在下被猝灭。通过同时使用不同的材料，我们能够测量不同分析物的指纹模式，并通过模式识别算法对其进行评估。该方法既可用于气相(电子鼻)，也可用于流体(电子舌)中硝基芳香族化合物的检测[2,3]。使用光电鼻，我们能够达到低于1ppb的检测极限。[1]张建军，张建军，张建军，等。遥感技术与应用，2017,32 (1):1 - 4N. Bolse等人，柔性和印刷电子，2024001 (2017)[3]N. Bolse等人，ACS Omega 2 (10)， 6500-6505 (2017)

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Organic and Hybrid Sensors and Bioelectronics XI

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