Speaker-Yaping Zhao
Dr. Yaping Zhao, an associate editor of The Journal of Supercritical Fluid, is a tenured Professor at the School of Chemistry and Chemical Engineering at Shanghai Jiao Tong University in China. He received his Ph.D. degree from Jiangsu University in 1997, and performed postdoctoral at Jiangnan University from 1997-1999. In 1999, he joined School of Chemistry and Chemical Engineering at Shanghai Jiao Tong University as an associate professor and became a professor in 2002. He worked as a visiting scholar at Chunbuk National University from 2005-2006, and at Stanford University from 2009-2010.
His research primarily focuses on the fundamental and applied aspects of Chemistry and Process Engineering in Supercritical Fluids, including the reaction, extraction, and separation of natural materials, as well as the preparation of advanced functional nanomaterials like graphene and other two-dimensional materials, and composites of 2D materials with polymers. He has published over 130 SCI articles and holds more than 20 patents. His achievements have facilitated the commercialization of applications utilizing supercritical fluids. In 2015, he was selected for a talent project in entrepreneurship and innovation in Jiangsu Province. He is a member of the ACS, ISASF, and the Supercritical Fluid Professional Committee of the Chinese Society of Chemical Engineering.
His research primarily focuses on the fundamental and applied aspects of Chemistry and Process Engineering in Supercritical Fluids, including the reaction, extraction, and separation of natural materials, as well as the preparation of advanced functional nanomaterials like graphene and other two-dimensional materials, and composites of 2D materials with polymers. He has published over 130 SCI articles and holds more than 20 patents. His achievements have facilitated the commercialization of applications utilizing supercritical fluids. In 2015, he was selected for a talent project in entrepreneurship and innovation in Jiangsu Province. He is a member of the ACS, ISASF, and the Supercritical Fluid Professional Committee of the Chinese Society of Chemical Engineering.
Title:Coupled Supercritical CO2 and Mechanical Force Technology for Green, Efficient, and Low-Cost Scalable Production of Graphene and Its Applications
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Abstract
Graphene, with its excellent electrical, thermal, and mechanical properties, has demonstrated vast potential for applications in fields such as energy, environment, and advanced materials. However, the combined impact of quality, cost, production scale, and environmental factors has significantly limited its practical application in the downstream industrial chain. Thus, achieving high-quality, sustainable, and low-cost industrial production of graphene remains a significant challenge. Supercritical carbon dioxide, as a unique green solvent, has shown exceptional advantages in various industrial fields.
This report presents an innovative technology that combines supercritical carbon dioxide with mechanical force to address the challenges of graphene's industrial production and widespread downstream applications. We will introduce the fundamental principles of this technology, the structure and properties of the graphene produced, and its applications in fields such as composites, supercapacitors, and sensors. Finally, we will explore the future development of this technology, offering new solutions for the broad commercial application and sustainable development of graphene.
This report presents an innovative technology that combines supercritical carbon dioxide with mechanical force to address the challenges of graphene's industrial production and widespread downstream applications. We will introduce the fundamental principles of this technology, the structure and properties of the graphene produced, and its applications in fields such as composites, supercapacitors, and sensors. Finally, we will explore the future development of this technology, offering new solutions for the broad commercial application and sustainable development of graphene.
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