Yiqiang Fan scite author profile

SUMMARYThis paper presents a resonance-based wireless power transfer system using a single layer of inductor coil windings, in a pancake configuration, in order to obtain a compact system for implantable electronic applications. We theoretically analyzed the system and characterized it by measuring its inductance, self-resonant frequency, and quality factor Q. In our resonance-based wireless power transfer prototype, we proposed a 3-coil system, using two 15-mm radius implantable coils, with a resonance frequency of 6.76 MHz. This system can effectively transfer power for a distance of up to 50 mm. Moreover, our proposed 3-coil system can achieve a high Q-factor and has a comparable power transfer efficiency (PTE) to previously reported works about 3-coil and 4-coil systems. The experimental PTE can achieve 82.4% at a separation distance of 20 mm and more than 10% PTE at a distance of 40 mm.

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Fabrication of polystyrene microfluidic devices using a pulsed CO2 laser system

Fan

Kodzius

et al. 2011

Microsyst Technol

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In this article, we described a simple and rapid method for fabrication of droplet microfluidic devices on polystyrene substrate using a CO 2 laser system. The effects of the laser power and the cutting speed on the depth, width and aspect ratio of the microchannels fabricated on polystyrene were investigated. The polystyrene microfluidic channels were encapsulated using a hot press bonding technique. The experimental results showed that both discrete droplets and laminar flows could be obtained in the device.

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Injection molding and characterization of PMMA-based microfluidic devices

Jin

et al. 2019

Microsyst Technol

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Rapid prototyping of cyclic olefin copolymer based microfluidic system with CO2 laser ablation

et al. 2017

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Fabrication and testing of metal/polymer microstructure heat exchangers based on micro embossed molding method

Zhuang

Hu²,

Fan

et al. 2018

Microsyst Technol

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Applications of Modular Microfluidics Technology

Fan

Wang

Gao

et al. 2018

Chinese Journal of Analytical Chemistry

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Laser micromachined wax-covered plastic paper as both sputter deposition shadow masks and deep-ultraviolet patterning masks for polymethylmethacrylate-based microfluidic systems

Fan

et al. 2013

J. Micro/Nanolith. MEMS MOEMS

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Abstract. We report a technically innovative method of fabricating masks for both deep-ultraviolet (UV) patterning and metal sputtering on polymethylmethacrylate (PMMA) for microfluidic systems. We used a CO 2 laser system to cut the required patterns on wax-covered plastic paper; the laser-patterned wax paper will either work as a mask for deep-UV patterning or as a mask for metal sputtering. A microfluidic device was also fabricated to demonstrate the feasibility of this method. The device has two layers: the first layer is a 1-mm thick PMMA substrate that was patterned by deep-UV exposure to create microchannels. The mask used in this process was the laser-cut wax paper. The second layer, also a 1-mm thick PMMA layer, was gold sputtered with patterned wax paper as the shadow mask. These two pieces of PMMA were then bonded to form microchannels with exposed electrodes. This process is a simple and rapid method for creating integrated microfluidic systems that do not require cleanroom facilities.

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Fully enclosed paper-based microfluidic devices using bio-compatible adhesive seals

et al. 2017

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Yiqiang Fan

Design and optimization of a 3‐coil resonance‐based wireless power transfer system for biomedical implants

Fabrication of polystyrene microfluidic devices using a pulsed CO2 laser system

Injection molding and characterization of PMMA-based microfluidic devices

Rapid prototyping of cyclic olefin copolymer based microfluidic system with CO2 laser ablation

Fabrication and testing of metal/polymer microstructure heat exchangers based on micro embossed molding method

Applications of Modular Microfluidics Technology

Laser micromachined wax-covered plastic paper as both sputter deposition shadow masks and deep-ultraviolet patterning masks for polymethylmethacrylate-based microfluidic systems

Fully enclosed paper-based microfluidic devices using bio-compatible adhesive seals

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