Prof. Xiaoxiao Huang is a leading researcher at the Harbin Institute of Technology, specializing in lightweight carbon-based and dielectric microwave absorption materials. She has authored 141 peer-reviewed articles and serves as an Associate Editor for the Journal of Advanced Ceramics. Prof. Huangβs groundbreaking work includes refining dielectric properties through quantitative doping and developing novel methods for interface polarization control, advancing stealth technology. With 3954 citations, 16 patents, and a published book, her contributions to materials science are globally acclaimed. Prof. Huangβs innovative research positions her as a pioneer in electromagnetic wave applications. πβ¨π
Prof Xiaoxiao Huang, School of Materials Science and Engineering, Harbin Institute of Technology, China
Profile
ORCID
SCOPUS
Educator and Researcher ππ
Prof. Xiaoxiao Huang has devoted her academic career to advancing the understanding of wide-band and high-intensity electromagnetic wave loss mechanisms in lightweight carbon-based and dielectric microwave absorption materials. Her work delves into the intricate science of improving material performance for cutting-edge applications, such as stealth technologies and electromagnetic interference reduction. Through her research, she has significantly contributed to the field of materials science, establishing herself as a thought leader in the study of advanced dielectric and carbon-based composites. Prof. Huangβs dedication to education and innovation continues to inspire advancements in the scientific community. ππ¬π
Experienceππ
Prof. Xiaoxiao Huang is a dedicated academic and researcher at the Harbin Institute of Technology, Harbin, China. Her work focuses on the wide-band and high-intensity electromagnetic wave loss mechanisms in lightweight carbon-based and dielectric microwave absorption materials. With extensive expertise in developing advanced materials, Prof. Huang has contributed to significant innovations in materials science, particularly in enhancing microwave absorption technologies for industrial and defense applications. Her commitment to research excellence and academic mentorship reflects her pivotal role in advancing science and technology. ππ¬β¨
Research and Innovations ππ¬
Prof. Xiaoxiao Huang has an exceptional track record in materials science research, completing 5 major projects and authoring 141 peer-reviewed journal articles indexed in SCI and Scopus. She has earned 3954 citations and published 16 patents, with 21 patents under process. Prof. Huang has also authored a book (ISBN: 978-7-5603-8432-0), further showcasing her expertise. Her editorial roles as Associate Editor for the Journal of Advanced Ceramics and Guest Editor for Nanomaterials highlight her influence in academia. Through her groundbreaking research and innovations, she continues to advance the field of microwave absorption materials. πβ¨π
Research Focus ππ¬
Prof. Xiaoxiao Huang’s research focuses on electromagnetic wave absorbing materials, with a particular emphasis on lightweight carbon-based composites and dielectric materials. Her work involves designing advanced materials with superior wave absorption capabilities, achieved through surface plasmon resonance, interface polarization effects, and heterostructure engineering. Prof. Huang’s innovative studies address challenges like impedance matching and broadband wave absorption, essential for applications in stealth technology and microwave shielding. Her impactful research, published in leading journals, showcases her expertise in bridging materials science and practical technological solutions. ππ‘β¨
Achievements ππ
Prof. Xiaoxiao Huang has made extraordinary contributions to materials science, amassing 3,954 citations and holding 16 published patents with an additional 21 patents in process. Her pioneering work is recognized globally, reflecting her innovative approach and expertise in advanced materials. Prof. Huang authored a book (ISBN: 978-7-5603-8432-0), which underscores her thought leadership in the field. Her groundbreaking research spans both academic exploration and industrial application, driving advancements in electromagnetic wave absorption and materials technology. Her achievements solidify her position as a trailblazer in materials science and a visionary in technological innovation. ππβ¨
Publication Top Notes πβ¨
π Mechanical characteristics and in vitro degradation kinetics analysis of polylactic glycolic acid/Ξ²-tricalcium phosphate (PLGA/Ξ²-TCP) biocomposite interference screw
ποΈ Polymer Degradation and Stability
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April 2021
π Sandwich structural TixOy-Ti3C2/C3N4 material for long life and fast kinetics Lithium-Sulfur Battery: Bidirectional adsorption promoting lithium polysulfide conversion
ποΈ Chemical Engineering Journal
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April 2021
π Tunable electromagnetic wave absorbing properties of carbon nanotubes/carbon fiber composites synthesized directly and rapidly via an innovative induction heating technique
ποΈ Carbon
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April 2021
π O-, N-Coordinated single Mn atoms accelerating polysulfides transformation in lithium-sulfur batteries
ποΈ Energy Storage Materials
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March 2021
π Construction of a CuβSn Heterojunction Interface Derived from a Schottky Junction in Cu@Sn/rGO Composites as a Highly Efficient Dielectric Microwave Absorber
ποΈ ACS Applied Materials & Interfaces
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March 2021