Your search keyword '"Qing-Hui Jin"' showing total 4 results

1. Flexible Solution-Gated Graphene Field Effect Transistor for Electrophysiological Recording.

Author

Ji Cheng, Lei Wu, Xiao-Wei Du, Qing-Hui Jin, Jian-Long Zhao, and Yuan-Sen Xu

Subjects

GRAPHENE, FIELD-effect transistors, ELECTROPHYSIOLOGY, ELECTROLYTES, MICROFABRICATION, BIOCOMPATIBILITY

Abstract

Graphene represents a high-performance material for field effect transistor (FET) manufacture. As a monolayer of carbon atoms, graphene offers flexibility, high carrier mobility, and transparency. Solution-gated graphene FETs based on flexible substrates have been developed for various applications. However, none of these FETs offer both flexibility and good insulation from the electrolyte simultaneously. This would restrict their applicability in certain areas, such as implantation. To solve this problem, we used commercially available graphene and polyimide to fabricate a graphene FET. Photosensitive polyimide was used as both substrate and insulator for our device. Two Au electrodes were used separately as source and drain, and the graphene was exposed to an electrolytic solution to form a solution-gated structure. In this paper, we have studied the resistance variation between source and drain during specific fabrication steps to optimize the fabrication process. By analyzing the FET performance after repeated bending tests, our device's performance reliability was also confirmed. When compared with similar published flexible devices, our FET showed higher transconductance and lower noise levels. Also, neural activities were recorded from cortex neurons cultured on graphene FET for the first time, which proved our device's biocompatibility and demonstrated its potential for electrophysiological applications. [ABSTRACT FROM AUTHOR]

Published

2014

2. Integration of Au Nanorods With Flexible Thin-Film Microelectrode Arrays for Improved Neural Interfaces.

Author

Hong-Bo Zhou, Gang Li, Xiao-Na Sun, Zhuang-Hui Zhu, Qing-Hui Jin, Jian-Long Zhao, and Qiu-Shi Ren

Subjects

THIN films, INTERFACES (Physical sciences), ALUMINUM oxide, ELECTRODES, MICROELECTRODES, PROSTHETICS

Abstract

In neural prosthetic systems, a low-impedance electrode-tissue interface is important for maintaining signal quality for recording, as well as effective charge transfer for stimulation. However, neural microelectrodes often have high impedance due to their small surface areas. In this paper, we present a simple method of increasing their effective surface areas by introducing nanostructures on the electrode sites. The method combines photolithography and electron-beam evaporation with a locally patterned anodized porous alumina template to integrate Au-nanorod arrays on the flexible thin-film microelectrode, which can significantly increase the effective surface area and decrease impedance due to its 3-D and compact nanostructures. Moreover, the geometrical and electrical properties of Au-nanorod electrodes were demonstrated and compared with conventional planar microelectrodes by using a scanning electron microscope and an impedance spectroscopy system. Experimental results showed that approximately 25 times lower interface impedance was achieved for this nanostructured microelectrode. Such Au-nanorod integrated microelectrode arrays will be a promising tool for neural engineering. [ABSTRACT FROM AUTHOR]

Published

2009

3. A Rapid and Low-Cost Procedure for Fabrication of Glass Microfluidic Devices.

Author

Qiang Chen, Gang Li, Qing-Hui Jin, Jian-Long Zhao, Qiu-Shi Ren, and Yuan-Sen Xu

Subjects

SOLID freeform fabrication, COMPUTER integrated manufacturing systems, MICROFLUIDICS, FLUID dynamics, FLUID mechanics, AERODYNAMICS, ELECTROHYDRODYNAMICS, FUSED silica, QUALITY control

Abstract

In this paper, we present a simple, rapid, and low-cost procedure for fabricating glass microfluidic chips. This procedure uses commercially available microscopic slides as substrates and a thin layer of AZ 4620 positive photoresist (PR) as an etch mask for fabricating glass microfluidic components, rather than using expensive quartz glasses or Pyrex glasses as substrates and depositing an expensive metal or polysilicon/amorphous silicon layer as etch masks in conventional method. A long hard-baking process is proposed to realize the durable PR mask capable of withstanding a long etching process. In order to remove precipitated particles generated during the etching process, a new recipe of buffered oxide etching with addition of 20% HCI is also reported. A smooth surface microchannel with a depth of more than 110 μm is achieved after 2 h of etching. Meanwhile, a simple, fast, but reliable bonding process based on UV-curable glue has been developed which takes only 10 mm to accomplish the efficient sealing of glass chips. The result shows that a high bonding yield (∼100%) can be easily achieved without the requirement of clean room facilities and programmed high-temperature furnaces. The presented simple fabrication process is suitable for fast prototyping and manufacturing disposable microfluidic devices. [ABSTRACT FROM AUTHOR]

Published

2007

4. A novel miniaturized PCR multi-reactor array fabricated using flip-chip bonding techniques.

Author

Zhi-Qing Zou, Xiang Chen, Qing-Hui Jin, and Meng-Su Yang and Jian-Long Zhao

Published

2005