METALS AND METAL MATRIX COMPOSITES |
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Preparation and Application in Sensing Fields of Gold Nanowires |
JIN Jiawei, LIU Chuanyang, ZHANG Ye, LIU Guowei, CHU Zengyong, LI Gongyi
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College of Liberal Arts and Sciences, National University of Defense Technology, Changsha 410073, China |
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Abstract In addition to the properties of ordinary nanomaterials (surface effect, dielectric confinement effect, small size effect and quantum tunneling effect), gold nanomaterials also have unique stability, electrical conductivity, excellent biocompatibility, supramolecular recognition, fluorescence and other characteristics, which broad their application prospects in the fields of nanoelectronics, optoelectronics, sensing and catalysis, biolabeling and biosensing. Among various forms of gold nanomaterials, the gold nanowires have always been highly valued by researchers. Therefore, exploring new technologies and new methods for preparing gold nanowires and further expanding their application fields are the research focuses in the field of nanomaterials. Gold nanowires have a large aspect ratio, good flexibility and their preparation methods are also relatively simple, thus, they have been extensively adopted in the fields of sensors, microelectronics, optical devices, surface enhanced Raman and biological detection. With the development of technology, researchers have developed a variety of methods for preparing gold nanowires, including template synthesis method, solution method, and edge modification method. However, in recent years, the application requirements in the fields of nanoelectronics and sensors have put forward higher requirements for the preparation of gold nanowires, such as a better morphology (diameter and geometry of gold nanowires) for gold nanowires, the complexity of the method, environmental pollution and production rate. Combining the novel preparation method and application of gold nanowires in the past ten years, this paper reclassifies the preparation methods and regulation methods of gold nanowires, and comprehensively summarizes the application of gold nanowires in the sensing field, in order to provide an overview for researchers.
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Published: 16 January 2020
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About author:: Jiawei Jin, born in 1995. In 2017, he graduated from the National University of Defense Technology with a bachelor's degree in applied chemistry. From 2017 to now, he is a master of environmental engineering at the National University of Defense Technology. His main research directions are nanomaterials and their chemical sensing applications;Gongyi Liwas born in 1980. In 2010, he graduated from the National University of Defense Technology with a Ph.D. In the same year, he stayed in school and was promoted to associate professor in 2015. His main research directions are the preparation of inorganic nanomaterials and its application in chemical sensors;Zengyong Chu, male, researcher at the School of Arts and Sciences, National University of Defense Technology. In 2003, he received his Ph.D. from the National University of Defense Technology. He then stayed in school to conduct teaching and research work. He was a visiting scholar at the Department of Chemistry, Oxford University from 2008 to 2009. He is a researcher at the National University of Defense Technology from 2012 to now. He was awarded the Hunan Outstanding Youth Science Foundation in 2013. His main research interests are wearable flexible sensor parts for individual soldiers, camouflage stealth functional materials and devices. |
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