Your search keyword '"Qin Xiangzheng"' showing total 3 results

1. Mechanical/Electrical Characterization of ZnO Nanomaterial Based on AFM/Nanomanipulator Embedded in SEM.

Author

Liu, Mei, Su, Weilin, Qin, Xiangzheng, Cheng, Kai, Ding, Wei, Ma, Li, Cui, Ze, Chen, Jinbo, Rao, Jinjun, Ouyang, Hangkong, Sun, Tao, Ahmed, Daniel, and Dokmeci, Mehmet Remzi

Subjects

ZINC oxide, ATOMIC force microscopes, YOUNG'S modulus, SCANNING electron microscopes, SURFACE morphology, TUNGSTEN alloys, TUNGSTEN trioxide

Abstract

ZnO nanomaterials have been widely used in micro/nano devices and structure due to special mechanical/electrical properties, and its characterization is still deficient and challenging. In this paper, ZnO nanomaterials, including nanorod and nanowire are characterized by atomic force microscope (AFM) and nanomanipulator embedded in scanning electron microscope (SEM) respectively, which can manipulate and observe simultaneously, and is efficient and cost effective. Surface morphology and mechanical properties were observed by AFM. Results showed that the average Young's modulus of ZnO nanorods is 1.40 MPa and the average spring rate is 0.08 N/m. Electrical properties were characterized with nanomanipulator, which showed that the ZnO nanomaterial have cut-off characteristics and good schottky contact with the tungsten probes. A two-probe strategy was proposed for piezoelectric property measurement, which is easy to operate and adaptable to multiple nanomaterials. Experiments showed maximum voltage of a single ZnO nanowire is around 0.74 mV. Experiment criteria for ZnO manipulation and characterization were also studied, such as acceleration voltage, operation duration, sample preparation. Our work provides useful references for nanomaterial characterization and also theoretical basis for nanomaterials application. [ABSTRACT FROM AUTHOR]

Published

2021

2. Frying Oil Evaluation by a Portable Sensor Based on Dielectric Constant Measurement.

Author

Liu, Mei, Qin, Xiangzheng, Chen, Zhanghao, Tang, Lei, Borom, Brandon, Cao, Ning, Barnes, Daniel, Cheng, Kai, Chen, Jinbo, Wang, Tao, and Rao, Jinjun

Subjects

*DIELECTRIC measurements, *PERMITTIVITY, *CAPACITIVE sensors, *DETECTORS, *INSULATING oils

Abstract

A portable capacitive sensor was designed to assess frying oil degradation by measuring the changes in electrical capacitance. An interdigital electrode (IDE) was designed to be implemented as the testing probe (as IDEs are resistive to parasitic capacitance), together with an adjacent capacitive chip Pcap01 and a further microprocessor STM32, which were used as the data-processing elements. Experimental results demonstrated that viscosity could be a useful frying oil quality indicator, and also proved a preliminary correlation between IDE capacitance and oils' total polar materials. This implies that IDE capacitance could be a suitable metric for conveniently assessing frying oil degradation. The designed capacitance sensor is light in weight, cost effective, and has excellent potential for simple, inexpensive, on-the-spot testing of the current quality of frying oil. [ABSTRACT FROM AUTHOR]

Published

2019

3. Interactive Manipulation of Nonconductive Microparticles in Scanning Electron Microscope by a Virtual Nano-Hand Strategy.

Author

Liu, Mei, Cheng, Kai, Qin, Xiangzheng, Wei, Zhenzhong, Borom, Brandon, Su, Weilin, Chen, Jinbo, Feng, Yunpeng, Wang, Tao, and Rao, Jinjun

Subjects

SCANNING electron microscopes, SCANNING electron microscopy, MICRURGY, ELECTRON microscopes

Abstract

Micro/nano-manipulation is the fabrication of particular constructs on devices at the micro/nano-scale. Precise manipulation of microparticles is one of the key technological difficulties in manufacturing micro/nano-scale components. Based on scanning electron microscopy and nanomanipulator, this paper adopts a direct push method to operate randomly distributed microparticles into ordered structures. A two-probe interaction strategy is proposed to enable microparticle movements in all directions efficiently and avoid scratching the substrate surface. To overcome the uncertainties in micromanipulation, a virtual nano-hand strategy was also implemented: long-range advance of each microparticle is realized by multiple single-step pushes, whose trajectory is theoretically analyzed. The pushes are well programmed to imitate effects of a more powerful and determined hand. Experimental results show that the theoretical single-step motion trajectory is in line with actual operation, and the proposed strategy can ensure precise operation of the microparticles in all directions and improve reliability and effectiveness of operation. [ABSTRACT FROM AUTHOR]

Published

2019