Mr. Xiaoyi Hou | New energy storage materials | Best Researcher Award 

Associate professor, Qinghai Normal University, China

Xiaoyi Hou is a dedicated researcher in the field of new energy storage technologies, with a strong background in condensed matter physics. A graduate of Lanzhou University, he has cultivated a specialized research portfolio focused on lithium-ion batteries, supercapacitors, and lithium-sulfur batteries. Hou’s work integrates fundamental science with practical applications, contributing significantly to the advancement of next-generation energy storage devices. In recognition of his impactful research, he was selected in 2019 as one of the top talents in Qinghai Province under the prestigious “Thousand Talents Plan for High-end Innovative Talents.” His scholarly contributions are evident in numerous publications in high-impact journals such as the Chemical Engineering Journal, Journal of Alloys and Compounds, and Materials Letters. Hou continues to drive innovations in materials science and electrochemical energy storage systems, making him a valuable figure in the field of sustainable energy technologies.

Professional Profile

• Scopus

Education

Xiaoyi Hou completed his academic training in condensed matter physics at Lanzhou University, a leading institution known for its strengths in physical sciences and materials research. His education provided him with a solid foundation in the principles of quantum mechanics, materials properties, and solid-state physics. During his academic tenure, he developed a particular interest in the application of physical principles to real-world energy challenges. His coursework and research projects exposed him to advanced topics in materials science, thermodynamics, and nanotechnology, which later became central to his career in energy storage. The comprehensive and interdisciplinary nature of his education at Lanzhou University equipped him with both theoretical knowledge and practical skills in materials characterization, device fabrication, and electrochemical testing. This educational background laid the groundwork for his transition into high-impact research in new energy materials and positioned him well for selection into competitive research talent programs in China.

Experience 

Xiaoyi Hou has accumulated significant experience in both academic and applied research on energy storage technologies. After graduating from Lanzhou University, he engaged in extensive laboratory and project-based research focused on the development of novel electrode materials and device architectures for next-generation energy storage systems. His experience spans lithium-ion batteries, lithium-sulfur batteries, and supercapacitors, where he has contributed to material synthesis, performance optimization, and device integration. He has worked on interdisciplinary teams involving physicists, chemists, and engineers, facilitating a holistic approach to problem-solving in energy systems. Hou has also led and participated in several provincial and national research projects, driving innovation in energy-efficient technologies. His research outcomes have been published in leading journals and have contributed to the scientific understanding and commercial potential of energy storage materials. His work continues to bridge the gap between fundamental materials science and functional energy devices.

Research Focus 

Xiaoyi Hou’s research focuses on the design and development of advanced materials for energy storage applications, with an emphasis on high-performance lithium-ion batteries, lithium-sulfur batteries, and supercapacitors. His work aims to address critical challenges such as energy density, cycle life, safety, and cost-effectiveness. He investigates novel electrode and electrolyte materials using nanostructuring, surface modification, and hybridization strategies to improve electrochemical performance. Hou also explores the mechanisms of charge storage and degradation processes at the molecular level, combining experimental techniques with theoretical modeling. His interdisciplinary approach bridges physics, materials science, and electrochemistry, enabling the creation of innovative storage devices with enhanced functionality. By focusing on scalable and sustainable materials, his research contributes to the advancement of clean energy technologies, addressing both environmental concerns and growing energy demands. Hou’s work continues to impact both academic inquiry and practical device innovation in the global energy storage sector

Publication Top Notes

Building Rapid Electron/Ion Dual Channels in Mesoporous CoSe₂/CNTs Composites for Advanced Sodium‑Ion Storage

• Authors: Xiaoyi Hou, Dengdeng Ai, Jianglong Kang, Qirongxing Shen, Minmin Li & Jingyu Qi

• Journal: Electrochimica Acta 530 (May 2025)

• Summary: This work presents a 3‑dimensional mesoporous CoSe₂–carbon‑nanotube hybrid using an MOF‑derived template. The structure provides intertwined electron and Na⁺ conduction channels, resulting in significantly improved sodium-storage metrics—higher capacity, enhanced rate performance, and longer cycling life compared to conventional CoSe₂ systems sciencedirect.com+7researchgate.net+7pubs.rsc.org+7.

Boosting Li⁺ Transport Kinetics and Structural Stability of Co‑Free LiNi₀.₉Mn₀.₁₋ₓAlₓO₂ Cathode Materials

• Authors: (not listed; placeholder “…, …”)

• Journal: Journal of Electroanalytical Chemistry, 2025

• Summary: Reported is a Co‑free layered cathode LiNi₀.₉Mn₀.₁₋ₓAlₓO₂ synthesized via organic‑amine co‑precipitation. Partial Al doping enhances lithium‑ion diffusion and stabilizes the layered structure under cycling conditions, yielding improved rate capability and structural integrity.

Improving the Electrochemical Performance of Ag‑Doped Ni‑Rich Li(Ni₀.₈₈Co₀.₀₉Al₀.₀₃)₁₋ₓO₂ Layered Cathode Material

• Authors: (not listed; placeholder “…, …”)

• Journal: Applied Physics A: Materials Science & Processing, 2025

• Summary: Silver‑doped Li(Ni₀.₈₈Co₀.₀₉Al₀.₀₃)O₂ is produced through solid‑state synthesis. It achieves a high initial discharge capacity (~223 mAh g⁻¹ at 0.2 C) and ~95% retention (~178 mAh g⁻¹) after 100 cycles. Ag doping stabilizes the structure, mitigating capacity fade.

A Tailored High‑Nickel Cobalt‑Free Na‑Doped LiNi₀.₉Mn₀.₀₆Al₀.₀₄O₂ Cathode for Superior Lithium Storage

• Authors: (not listed; placeholder “…, …”)

• Journal: Physical Chemistry Chemical Physics, June 25 2025

• Summary: This Na-doped, high-Ni, Co-free cathode material fine-tunes the lattice of LiNi₀.₉Mn₀.₀₆Al₀.₀₄O₂ to enhance Li⁺ transport kinetics and structural robustness. Results show high capacity and excellent cycling stability, attributing improvements to optimized lattice spacing and diffusion pathways.

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