Kwun Nam Hui
Institute of Applied Physics and Materials Engineering, University of Macau, Macau SAR, China
Dr. Kwun Nam HUI is currently an Associate Professor at the Institute of Applied Physics and Materials Engineering, University of Macau, Macau SAR, China. Before this, he was Associate Professor atPusan National University, Republic of Korea. His current research focuses on the synthesis of hierarchical carbon/graphene materials as well as on the development of 3D hierarchical layered double hydroxide materials as advanced electrode materials for energy storage and conversion applications. He has published more than 150 journal articles with a citation of over 4000 times and an h-index of 38.
Keynote Speech Topic:
Rational Design of Metal Oxides for High-Performance Supercapacitor
The stringent requirements for reliable supercapacitors have increased because of their rapidly growing commercial markets for electronic devices. Supercapacitors can be divided into two types based on their charge storage mechanism: electrical double layer capacitors (EDLCs) and pseudocapacitors. EDLCs typically use carbon-based electrodes such activated carbon, carbon nanotube, and graphene for charge storage through electrostatic accumulation of surface charge. Pesudocapacitors store energy in rapid fast reversible Faradaic reactions at the surface, intercalation, or adsorption, resulting in higher energy densities [5, 6]. However, the intrinsically poor electrical conductivity and insufficient number of electrochemically active sites of transition-metal oxides hamper their wide application in high-performance supercapacitors. The demand for supercapacitors with favorable energy and power densities hasstimulated tremendous research interest on the exploration of novel nanostructured metal oxide electrode materials.
In this talk, several strategies, including the morphology control, core/shell architecture, and defect engineering, will be discussed to improve the electron transports, electrolyte ions diffusion kinetics, and electrical conductivity of metal oxide-based electrodes.Experimental analyses and theoretical calculations reveal that the electronic structure of metal oxides can be efficiently modulated by incorporating heteroatoms and oxygen vacancies, thereby simultaneously reducing the energy band gap and increasing electrical conductivity. In particular, the heteroatomsdoping approach is demonstrated to lower the diffusion barrier of electrolyte ions in intercalated supercapacitors.

Member Center

Online Submission

Key Date to Keep in Mind
Submission Deadline
August 15, 2020
Notification of Acceptance from

August 31, 2020

(Within 2 weeks after submission)

Early Bird Registration Deadline
September 25, 2020

Final Registration Deadline
October 15, 2020