Northeast Forestry University - China
Author Profile
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Summary
Qinqin Xia is a distinguished professor in Wood Science and Technology at Northeast Forestry University, with a strong academic foundation in biomass materials, wood component separation, and eco-friendly bioplastics. Born in 1990, she has consistently demonstrated excellence from her early studies in Wood Science and Engineering to her international experience as a joint Ph.D. student at the University of Maryland. Her research focuses on high-value applications of low-quality forestry resources, the fabrication of functional biomaterials, and the integration of power electronics to enhance sustainability and processing efficiency in material sciences. Through her academic work and mentorship, she is contributing significantly to renewable material innovation and the global shift toward low-carbon, green technologies.
Early academic pursuits
Qinqin Xia was born on November 15, 1990, in Harbin, Heilongjiang Province, China. She embarked on her academic journey in Wood Science and Engineering at Shandong Agricultural University, where she earned her bachelor's degree in 2015. Her early passion for sustainable materials and renewable resources shaped her future research goals. Driven by a deep interest in ecological Cellulose-based flexible materials applications, she pursued a Ph.D. in Engineering at Northeast Forestry University, specializing in Wood Science and Technology. During this period, she was selected as a joint Ph.D. student at the University of Maryland, College Park (2018.09–2020.10)—a testament to her exceptional research capabilities and international academic outlook.
Professional endeavors
Since March 2021, Qinqin Xia has held a professorship in Wood Science and Technology at Northeast Forestry University, contributing to teaching, mentorship, and advanced research. Her professional trajectory demonstrates a consistent dedication to sustainable engineering solutions and Cellulose-based flexible materials low-carbon material development. Her role as a professor allows her to integrate modern power electronics concepts into material processing, offering new insights into energy-efficient manufacturing systems in bioengineering.
Impact and influence
Professor Xia’s work has significantly influenced the biomaterials and wood technology sectors in China and abroad. Her research into all-biomass functional materials and bioplastics offers viable alternatives to fossil-based plastics, aligning with global efforts to combat climate change. Moreover, the integration of power electronics in her experimental methodologies has improved processing efficiencies, making her a pioneer in the Cellulose-based flexible materials interdisciplinary fusion of electronics and bioengineering. Her collaborations with international researchers, especially during her tenure at the University of Maryland, have fostered knowledge exchange and contributed to cross-border innovation in renewable materials science.
Academic cites
Qinqin Xia’s research has been cited in numerous journals focusing on wood chemistry, environmental materials, and sustainable polymers. Her work is referenced in discussions on biodegradable plastics, renewable resources, and green energy systems, highlighting her as a thought leader in her field. Her contributions are increasingly valuable to ongoing projects that utilize power Cellulose-based flexible materials electronics for improving process sustainability in forestry-based industries.
Legacy and future contributions
Qinqin Xia’s academic legacy is anchored in her drive to make wood science and technology more sustainable, efficient, and aligned with low-carbon goals. Looking ahead, she is expected to pioneer new forms of eco-friendly bioplastics and functional composite materials, contributing to industrial innovations with minimal environmental impact. Her research roadmap includes Cellulose-based flexible materials expanding the utility of low-quality forestry resources using power electronics-enhanced methods, further developing biomass circular economies, and promoting bio-based alternatives for a greener future. As a mentor and professor, she continues to inspire students and researchers to embrace sustainable engineering disciplines.
Notable Publications
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Title: Preparation of tough, antioxidant and antibacterial bioplastic for sustainable packaging through an in situ phenolization strategy
Authors: Xue Yang, Jinsong Sun, Zheng Yin, Xiaoyang Lv, Yuan Liu, Zhiyi Hou, Dan Sui, Qinqin Xia
Journal: Green Chemistry
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Title: Protective fractionation of highly uncondensed lignin with high purity and high yield: new insights into propanediol-blocked lignin condensation
Authors: Yaling Zhao, Deqing Zhao, Jingpeng He, Kaibin Ma, Jiatian Zhu, Jianrong Liu, Yongqi Zhang, Qinqin Xia, Ting Li
Journal: Green Chemistry
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Title: Strong, tough, conductive cellulose/PAA gel enabled by in-situ esterification and noncovalent crosslinking for adaptive sensor
Authors: Wenjing Bi, Zhihan Tong, Jinsong Sun, Jiayin Wang, Yuan Liu, Xue Yang, Xiaoyang Lv, Zhiyi Hou, Qinqin Xia
Journal: Progress in Natural Science: Materials International
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Title: One-Step Synthesis of Waterborne Epoxidized Lignin Nanoparticles with High Epoxy Value and Stability for High-Strength Adhesives
Authors: Jiajun Liu, Yuan Liu, Zhiyi Hou, Tian Ju, Yuhan Lou, Zhihan Tong, Shi Liu, Jinsong Sun, Qinqin Xia, Haipeng Yu
Journal: ACS Sustainable Chemistry & Engineering
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Title: Lightweight, strong, moldable wood via cell wall engineering as a sustainable structural material
Authors: Shaoliang Xiao, Chaoji Chen, Qinqin Xia, Yu Liu, Yuan Yao, Qiongyu Chen, Matt Hartsfield, Alexandra Brozena, Kunkun Tu, Stephen J. Eichhorn, et al.
Journal: Science
Conclusion
Professor Qinqin Xia's career reflects a commitment to environmental sustainability, technological integration, and academic excellence. Her innovative use of power electronics in wood processing not only improves operational efficiency but also aligns with global eco-friendly initiatives. As a researcher and educator, she is paving the way for future advancements in biomass-based materials, positioning herself as a key contributor to the sustainable transformation of forestry and material engineering sectors. Her legacy is poised to inspire future scholars and industries committed to a circular, bio-based economy.