Terahertz Characteristics of Magnetic Fluid Based on Microfluidic Technology

Terahertz Characteristics of Magnetic Fluid Based on Microfluidic Technology

Magnetic fluid is a new functional material with both liquid fluidity and solid magnetism, which has important application value in medicine, biology, and so on. In this study, terahertz technology and microfluidic technology were combined to investigate the terahertz transmission characteristics of...

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Main Authors: Xinyuan Zhao, Guoyang Wang, Siyu Shao, Qinghao Meng, Jiahui Wang, Sijia Zhang, Bo Su, Cunlin Zhang
Format: Article
Language:English
Published: Hindawi Limited 2021-01-01
Series:International Journal of Optics
Online Access:http://dx.doi.org/10.1155/2021/5599185
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spelling doaj-7c15ba2086b24209a6a2c9c9930562712021-06-21T02:25:05ZengHindawi LimitedInternational Journal of Optics1687-93922021-01-01202110.1155/2021/5599185Terahertz Characteristics of Magnetic Fluid Based on Microfluidic TechnologyXinyuan Zhao0Guoyang Wang1Siyu Shao2Qinghao Meng3Jiahui Wang4Sijia Zhang5Bo Su6Cunlin Zhang7Key Laboratory of Terahertz OptoelectronicsKey Laboratory of Terahertz OptoelectronicsKey Laboratory of Terahertz OptoelectronicsKey Laboratory of Terahertz OptoelectronicsKey Laboratory of Terahertz OptoelectronicsKey Laboratory of Terahertz OptoelectronicsKey Laboratory of Terahertz OptoelectronicsKey Laboratory of Terahertz OptoelectronicsMagnetic fluid is a new functional material with both liquid fluidity and solid magnetism, which has important application value in medicine, biology, and so on. In this study, terahertz technology and microfluidic technology were combined to investigate the terahertz transmission characteristics of a magnetic fluid in different magnetic fields and different electric fields. In the external magnetic field, the intensity of the terahertz spectrum increased with an increase in the magnetic field intensity, and the response to the magnetic field in different directions was different. Under the applied electric field, the intensity of the terahertz spectrum decreased with an increase in the electric field intensity. This method is convenient for studying the terahertz characteristics of magnetic fluid and provides technical support for in-depth studies of magnetic fluid.http://dx.doi.org/10.1155/2021/5599185
collection DOAJ
language English
format Article
sources DOAJ
author Xinyuan Zhao
Guoyang Wang
Siyu Shao
Qinghao Meng
Jiahui Wang
Sijia Zhang
Bo Su
Cunlin Zhang
spellingShingle Xinyuan Zhao
Guoyang Wang
Siyu Shao
Qinghao Meng
Jiahui Wang
Sijia Zhang
Bo Su
Cunlin Zhang
Terahertz Characteristics of Magnetic Fluid Based on Microfluidic Technology
International Journal of Optics
author_facet Xinyuan Zhao
Guoyang Wang
Siyu Shao
Qinghao Meng
Jiahui Wang
Sijia Zhang
Bo Su
Cunlin Zhang
author_sort Xinyuan Zhao
title Terahertz Characteristics of Magnetic Fluid Based on Microfluidic Technology
title_short Terahertz Characteristics of Magnetic Fluid Based on Microfluidic Technology
title_full Terahertz Characteristics of Magnetic Fluid Based on Microfluidic Technology
title_fullStr Terahertz Characteristics of Magnetic Fluid Based on Microfluidic Technology
title_full_unstemmed Terahertz Characteristics of Magnetic Fluid Based on Microfluidic Technology
title_sort terahertz characteristics of magnetic fluid based on microfluidic technology
publisher Hindawi Limited
series International Journal of Optics
issn 1687-9392
publishDate 2021-01-01
description Magnetic fluid is a new functional material with both liquid fluidity and solid magnetism, which has important application value in medicine, biology, and so on. In this study, terahertz technology and microfluidic technology were combined to investigate the terahertz transmission characteristics of a magnetic fluid in different magnetic fields and different electric fields. In the external magnetic field, the intensity of the terahertz spectrum increased with an increase in the magnetic field intensity, and the response to the magnetic field in different directions was different. Under the applied electric field, the intensity of the terahertz spectrum decreased with an increase in the electric field intensity. This method is convenient for studying the terahertz characteristics of magnetic fluid and provides technical support for in-depth studies of magnetic fluid.
url http://dx.doi.org/10.1155/2021/5599185
work_keys_str_mv AT xinyuanzhao terahertzcharacteristicsofmagneticfluidbasedonmicrofluidictechnology
AT guoyangwang terahertzcharacteristicsofmagneticfluidbasedonmicrofluidictechnology
AT siyushao terahertzcharacteristicsofmagneticfluidbasedonmicrofluidictechnology
AT qinghaomeng terahertzcharacteristicsofmagneticfluidbasedonmicrofluidictechnology
AT jiahuiwang terahertzcharacteristicsofmagneticfluidbasedonmicrofluidictechnology
AT sijiazhang terahertzcharacteristicsofmagneticfluidbasedonmicrofluidictechnology
AT bosu terahertzcharacteristicsofmagneticfluidbasedonmicrofluidictechnology
AT cunlinzhang terahertzcharacteristicsofmagneticfluidbasedonmicrofluidictechnology
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