2026

[1] Yang Liu, Zhenjun Shao, Jin Qian, Tiezhu Guo, Jian Bao, Diming Xu, Weichen Zhao, Zhentao Wang, Zilin Huang, Jiajia Ren, Jinnan Liu, Ziyang Liu, Jiwei Zhai*, Yao Zhou*, Zenghui Liu*, Tao Zhou*, Guiwei Yan, Jinzhan Su, Wenyuan Liu, Wenfeng Liu*, Jordi Jacas, Joan Ramon Morante Lleonart, Andreu Cabot, and Di Zhou,* Multilevel Heterointerface Engineering Breaks the Trap-Barrier Trade-Off in High-Energy-Density Polymer Dielectrics, Advanced Materials, 2026, 38[16], e17624.
[2] Da Li, Ze Zhang, Weichen Zhao, Ying Lin*, Jinming Guo, Haibo Yang*, Di Zhou*, Large Capacitive Energy Storage in Linear-Like MLCCs with Tailored Atomic-Scale Polymorphic Polarization Fluctuations, Advanced Materials, 2026, 38[11], e22382.
[3] Tao Liu, Yang Liu, Jin Qian, Jiwei Zhai,* Tao Zhou, Yao Zhou, Di-Ming Xu, Wenfeng Liu, and Di Zhou*, Enhanced Energy Storage Performance Through Electron-Hole Pair Formation in Polymer Matrices Doped with P-Type Molecular Semiconductor, Advanced Functional Materials, 2026, 36[6], e16202.
[4] Chang-Hao Wang, Kai-Heng Zhang, Jian Bao, Jia-Pei Jiang, Di-Ming Xu, Chao Du, Li-Xia Pang*, Tao Zhou*, Kar Ban Tan*, Di Zhou*, Novel Temperature-Stable (1-x)Ba3V2P3O15-xBaV2O6 Composite Ceramics with Ultralow Sintering Temperature and Low Dielectric Loss for Dielectric Resonator Antenna Applications, Advanced Functional Materials, 2026, 36[18], e22167.
[5] Guo-Qiang He, Chao Du, Zhentao Wang, Zhen Fang, Wei Wang, Zhaochen Xi, Chenchen Wu, Shuwei Ma, Moustafa Adel Darwish, Tao Zhou, Diming Xu, Song Xia, Yongzheng Wen, Kar Ban Tan, Di Zhou,* BaSc2O4: A Novel AB₂O₄-Type Low-k Microwave Dielectric Ceramic with Giant Positive τf for 5G/6G Frequency Compensation, Advanced Functional Materials, 2026, accepted, https://doi.org/10.1002/adfm.202528138.
[6] Zhaochen Xi, Zhentao Wang, Changqing Guo, Ke Xu, Weichen Zhao, Zhengqiao Li, Jian Bao, Haowei Zhou, Cong Zou, Houbing Huang* and Di Zhou*, Active learning optimization in latent spaces accelerates inverse design of ferroelectric ceramics for energy storage, Nature Communications, 2026, https://doi.org/10.1038/s41467-026-70792-7.
[7] Zhentao Wang, Weichen Zhao, Zhaochen Xi, Wenyuan Liu, Da Li, Diming Xu, Guoqiang He, Yang Liu, Guiwei Yan, Jian Bao, Zhen Fang, Xu Liang, Takahiro Shimada*, Chang Liu*, Tao Xu, Wenfeng Liu, Tao Zhou, Di Zhou*, Entropy-Regulated Local Multiphase Polarization States for Near-Zero Energy Loss in Relaxor Ferroelectrics, ACS Nano, 2026, 20, 10043−10052.
[8] Ying Han, Xiao Li*, Yang Liu, Jin Qian, Jianjun Liu, Diming Xu, Weichen Zhao, Haowei Zhou, Jiwei Zhai*, Tao Zhou*, Yao Zhou, Wenfeng Liu*, Di Zhou*, Superior dielectric energy storage performance at elevated temperatures enabled by precisely tailored MgO NPLs distribution in tri-layer polymer composites, Nano Energy, 2026, 147, 111587.
[9] Tao Liu, Jianjun Liu, Yang Liu, Jin Qian, Jiwei Zhai, Yao Zhou*, Tao Zhou, Gui-Wei Yan, Di-Ming Xu, Kar Ban Tan*, Wenfeng Liu, Di Zhou,* Interlayer-directed multilevel trap engineering for enhanced energy storage in PET dielectric films, Nano Energy, 2026, 147, 111613.
[10] Xiao Li, Tiezhu Guo*, Man Li, Chunyu Yang, Haowei Zhou, Yang Liu, Shoaib Iqbal, Zilin Huang, Moustafa A. Darwish, M.M. Salem, Tao Zhou, Di Zhou*, Overview of MXene-based sensors: Fundamentals and applications in gas sensors, biosensors, and mechanical sensors, Carbon, 2026, 247, 121015.
[11] Haowei Zhou, Xiao Li,*, Zilin Huang, Zhongming Liu, Man Li, Jieyan Zhang, Yu Wang, Zhaochen Xi, Moustafa Adel Darwish, Tao Zhou, Di Zhou,* "Cardiac-like functionalization" porous magnetic MXene/carbon dots films via constructing bidirectional electromagnetic wave attenuation paths for high-performance microwave absorption, Carbon, 2026, 250, 121298.
[12] Yang Liu, Yonghao Zhang, Tao Liu, Tiezhu Guo, Weichen Zhao, Tao Zhou*, Yao Zhou, Wenfeng Liu, Jordi Jacas, Joan Ramon Morante Lleonart, Andreu Cabot*, Di Zhou*, Breaking the energy density barrier in polymer film capacitors via molecular and interfacial design, Journal of Colloid and Interface Science, 2026, 703, 139174.
[13] Yu, Zhenfa; Wang, Chang-Hao; Wang, Xin; He, Guoqiang; Ma, Peiwen; Bao, Jian; Fang, Zhen; Xu, Diming; Pang, Li-Xia*; Zhou, Tao; Tan, Kar Ban; Zhou, Di*, Low-Temperature Sintered Ba16ZrNb12O48-BaWO4 Composite Ceramics with Near-Zero τf and Enhanced Q×f for LTCC Applications, Journal of the European Ceramic Society, 2026, 46, 118054.
[14] Diming Xu, Wei Wang, Ruitao Li, Zhen Fang, Shuwei Ma, Haobo Zhang, Tao Zhou, Wenfeng Liu, Di Zhou*, Highly enhanced dielectric tunable performance in Ba0.6Sr0.4TiO3 ceramics via Li2ZnTi3O8 addition, Journal of the European Ceramic Society, 2026, 46, 117775.
[15] Pei-Wen Ma, Chang-Hao Wang, Zhen-Fa Yu, Rui Zou, Tao Zhou,* Kar Ban Tan,* Di Zhou*, A Novel Low Permittivity CaP2O6 Microwave Dielectric Ceramics with Low Sintering Temperature by B2O3-CuO Additions, Journal of the European Ceramic Society, 2026, 46, 118210.
[16] Guo-Qiang He, Chao Du, Zhen-Tao Wang, Jian Bao, Zhen Fang, Chang-Hao Wang, Zhao-Chen Xi, Moustafa Adel Darwish, Tao Zhou, Di-Ming Xu, Song Xia, Yong-Zheng Wen, Kar Ban Tan*, Di Zhou*, High microwave dielectric performance and applications in antenna of novel Li7La3Zr2O12 ceramics, Journal of the American Ceramic Society, 2026, 109, e70425.
[17] Yu Wang, Xiao Li*, Haowei Zhou, Zilin Huang, Moustafa Adel Darwish, M.M. Salem, Tao Zhou, Murat Yilmaz, Azim Uddin, Di Zhou* Fe3O4-CNFs@MXene with Encapsulated Magnetic Nanoparticles for Tunable High-Performance Microwave Absorption via Dual Electromagnetic Wave Loss Pathways, Materials Today Physics, 2026, 62, 102043.
[18] 包健; 李正巧; 郭靖; 王昌昊; 席兆琛; 周迪*, 面向5G/6G无线通讯和先进封装技术的低介电常数无机电介质材料研究进展, 绝缘材料，2026，接收。
[19] Muhammad Shehbaz, Xiao Li*, Chao Du, Di-Ming Xu, Xiao-Gang Yao, Hui-Xing Lin, Tao Zhou, Zhong-Qi Shi, Song Xia, and Di Zhou,* Materials Engineering in Microwave Absorbers: Recent Advances and Prognosis, Journal of Materials Chemistry C, 2026, 14, 2091-2133.
[20] Yingying Zheng, Weihao Dai, Jian Wang*, Yifei Zhang, Biyun Peng, Fangfang Wu, Yunchuan Xie*, Sen Liang, Di Zhou,* Spatial-conformational locking of π-conjugated pathways enables 150–200 ℃ polyimides capacitive energy storage, Chemical Engineering Journal, 2026, 527, 171928.
[21] Sen Ren, Yaogong Wang*, Yan Qiu*, Boya Zhang, Yixuan Li, Chenxi Liu, Lixia Pang, Di Zhou, Yongdong Li, Dielectric breakdown strength and energy storage improvement of polyimide through environmentally benign reactive ion etching plasma surface modification, Chemical Engineering Journal, 2026, 527, 171507.
[22] Jinchao Miao, Guoqiang He,* Chao Du, Qin Guo, Baili Wang, Xinxiu Yang, Zhiqun Cheng, Tao Zhou,* Di Zhou*, Design of dielectric resonator antenna with temperature-stabilized BaZnAl10O17 microwave dielectric ceramics, Journal of Alloys and Compounds, 2026, 1051, 185899.
[23] Xingcai Wang, Yu Chen, Qijun Cheng, Di Zhou*, Design and fabrication of termination electrodes for high-reliability multi-layer ceramic capacitors, Materials Research Bulletin, 2026, 199, 114039.
[24] Jian Bao, Jing Guo, Tao Zhou,* Jia-Pei Jiang, Chao Du, Xin Wang, Zhao-Chen Xi, Li-Xia Pang,* Kar Ban Tan,* and Di Zhou*, ULTCC-Compatible LiPO3 Ceramic with Ultralow Permittivity for 5G High-Gain Antenna Array Applications, ACS Applied Materials & Interfaces, 2026, 18, 13980−13991.
[25] Ke Xu, Xiaoming Shi, Zhaochen Xi, Shouzhe Dong, Changqing Guo, Rongzhen Gao, Letao Yang, Jing Wang, Di Zhou, Houbing Huang*, Machine-Learning-Guided Design of Incommensurate Antiferroelectrics via Field-Driven Phase Engineering, Advanced Science, 2026, 13[22], e23873.
[26] Fang-Fang Wu, Ruixin Sun, Ling Zhang, Feng Qiao, Li-Xia Pang, Chao Du, Kar Ban Tan, Yao Wang, Qin Guo, Di Zhou*, Research progress on fergusonite structured K20 microwave ceramics and devices applications, Review of Materials Research, 2026, 2[3], 100184.
[27] Fang-Fang Wu, Ruixin Sun, Chao Du, Yao Tang, Diming Xu, Biao-Bing Jin, Chun Li, Guohua Chen, Heli Jantunen,* Di Zhou*, Internal-Stress-Driven Phase Stability and Temperature-Stable Microwave Ceramics of Sr2+/Mo6+ Co-Substituted Samarium Niobate as Dielectric Resonator for X-Band Antenna Applications, Materials Today Chemistry, 2026, 54, 103615.
[28] Kaiheng Zhang, Di Zhou*, Guodong Cai, Shaofei Wang, Yuanxi Cao, Sen Yan,* A dual-polarized metasurface with angle-selective character in elevation plane and stability in azimuth plane, Optics & Laser Technology, 2026, 200, 115213.

2025

[1] Da Li, Zhaobo Liu, Weichen Zhao, Yan Guo,Zhentao Wang, Diming Xu*,Houbing Huang*, Li-Xia Pang, Tao Zhou, Wen-Feng Liu*, Di Zhou,* Global-optimized energy storage performance in multilayer ferroelectric ceramic capacitors, Nature Communications, 2025, 16, 188.
[2] Zhentao Wang, Da Li, Wenyuan Liu, Liqiang He*, Diming Xu*, Jinnan Liu, Jiajia Ren, Xin Wang, Yang Liu, Guoqiang He, Jian Bao, Zhen Fang, Guiwei Yan, Xu Liang, Tao Zhou, Weichen Zhao*, Wenfeng Liu, Dong Wang* and Di Zhou,* Ultra-high energy storage in lead-free NaNbO3-based relaxor ceramics with directional slush-like polar structures design, Nature Communications, 2025, 16, 2892.
[3] Weichen Zhao, Zhaobo Liu, Diming Xu*, Ge Wang, Da Li, Jinnan Liu, Zhentao Wang, Yan Guo, Jiajia Ren, Tao Zhou*, Lixia Pang, Hongwei Yang, Wenfeng Liu*, Houbin Huang*, Di Zhou*, Advanced stability and energy storage capacity in hierarchically engineered Bi0.5Na0.5TiO3-based multilayer capacitors, Nature Communications, 2025, 16, 6549.
[4] Yuexin Lin, Zhichao Lin, Shili Lv, Yuan Shui, Wenjing Zhu, Zuhong Zhang, Wenhan Yang, Jinbo Zhao, Hao Gu, Junmin Xia, Danning Wang, Fenqi Du, Annan Zhu, Jin Liu, Hairui Cai, Bin Wang, Nan Zhang, Haibin Wang, Xiaolong Liu, Tao Liu, Chuncai Kong, Di Zhou, Shi Chen, Zhimao Yang, Tao Li, Wei Ma, Guojia Fang, Luis Echegoyen, Guichuan Xing*, Shengchun Yang*, Tao Yang*, Wenting Cai*, Meng Li*, Wei Huang & Chao Liang*, A Nd@C82-polymer interface for efficient and stable perovskite solar cells, Nature, 2025, 642, 78-84.
[5] Yan Guo, Weichen Zhao, Da Li, Jinnan Liu, Jin Qian, Lixia Pang,* Tao Zhou, Wenfeng Liu,* Zhaobo Liu, Houbing Huang,* Jiwei Zhai, and Di Zhou,* Ultra-high Capacitive Energy Storage Density at 150 °C Achieved in Polyetherimide Composite Films by Filler and Structure Design, Advanced Materials, 2025, 37 [6], 2415652.
[6] Fang-Fang Wu, Ruixin Sun, Chao Du, Diming Xu, Biao-Bing Jin, Chun Li, Heli Jantunen,* and Di Zhou*, P5+ Enhanced Novel Samarium Niobate Ultralow-loss Microwave Ceramics as Dielectric Resonator for X-Band Antenna Applications, Advanced Functional Materials, 2025, 35[22], 2421225.
[7] Zelin Zhang, Aibing Chen, Xiao Li,* Ruonan Li, Haowei Zhou, Zhongming Liu, Xinyue Zhang, Xudong Jing, Zhongxue Lin, Di Zhou, Biao Kong, and Lei Xie, Monolayer Interfacial Assembly toward Two-Dimensional Mesoporous Heterostructure for Boosting Wave Absorption, Advanced Functional Materials, 2025,35[24], 2420702.
[8] Jinnan Liu, Weichen Zhao,* Jiajia Ren, Wenyuan Liu, Da Li, Zhentao Wang, Yang Liu, Wenfeng Liu, Tao Zhou, Diming Xu,* Guohua Chen, Kar-Ban Tan, and Di Zhou*, Near-Zero Energy Dissipation Multilayer Ceramic Capacitors via Inhomogeneous Polarization Design, Small, 2025, 21[19], 2501062.
[9] Jian-Jun Liu, Di Zhou,* Superior High-Temperature Energy Storage Performance in All-Organic Composite Dielectrics Achieved by Synergistic Regulation of Free Volume and Charge Distribution, Small, 2025, 21[40], e07631.
[10] Tiezhu Guo, Wenfei Wei, Jiali Chai, Yuchuan Ren, Murat yilmaz, Azim Uddin, Andreu Cabot,* and Di Zhou*, Tailoring Surface Chemistry of Ti3C2Nx MXene for Superior H+, Li+, and Na+ Storage via Molten Salt-Derived N-Termination, Small, 2025, 21[48], e08556.
[11] Yan Guo, Ruitao Li, Weichen Zhao, Jin Qian, Tao Zhou, Wenfeng Liu,* Jiwei Zhai, Yonghao Xu, and Di Zhou,* High-Temperature Energy Storage Performance of PEI-Based Composites Enhanced by Core-Shell Structured Nanofillers, Small Structures, 2025, 6[11], 2500460.
[12] Tao Liu, Yang Liu, Jin Qian, Jiajia Ren, Jiwei Zhai,* Tao Zhou,* Yao Zhou, Gui-Wei Yan, DiMing Xu, Wenfeng Liu,* and Di Zhou,* A Simple Surface Engineering Approach to Enhance the Schottky Barrier of Polymer Dielectrics for Superior Energy Storage Performance, Journal of Materials Chemistry A, 2025, 13, 26279-26287.
[13] Chao Du, Shaofei Wang, Yongqiang Pang,* Zhongxiang Shen,* Kaida Xu, ZhijiWang, Tao Zhou, Song Xia, Di Zhou,⁎ Radiofrequency Transparent Uniaxial Dual-Polarized Metasurface with Ultrawide Brewster Angle Stability, Laser & Photonics Reviews, 2025, 19, 2500190.
[14] Xi, Zhaochen; Wang, Xin; Wang, Chang-Hao; Wang, Wei; Bao, Jian; Xu, Diming; He, Guoqiang; Zhou, Tao; Chen, Guohua; Xia, Song; Zhou, Di, Accelerating Low-k Dielectric Material Discovery: From Graph Machine Learning to Synthesis, ACS Applied Materials & Interfaces, 2025, 17, 28, 40743–40752.
[15] Wei Wang, Jian Bao, Changhao Wang, Ziyang Liu, Shuwei Ma, Diming Xu, Biaobing Jin, Zhongqi Shi, Moustafa Adel Darwish, Yawei Chen, Qixin Liang, Meirong Zhang, Di Zhou*, Low-permittivity LiMSiO4 (M = Ga, Sc, Y) Dielectric Ceramic and Microstrip Array Antenna Design for Millimeter-wave Communications, Journal of Materials Science & Technology, 2025, 225, 288–296.
[16] Yang Liu, Jin Qian, Yan Guo, Weichen Zhao, Tiezhu Guo, Diming Xu, Zhentao Wang, Guoqiang He, Jiwei Zhai, Yao Zhou, Wenfeng Liu, and Di Zhou*, High Energy Storage Density Achieved in Polymer Composites by Hierarchical Interface Engineering Design, Chemical Engineering Journal, 2025, 505, 159343.
[17] Jing Li*, Lingling He, Weimin Xia, Chao Du, Li He, Xiao Li, Caiyin You, Di Zhou*, Constructing heterogeneous interfaces of Ti3C2Tx MXene magnetic nanocomposites for efficient low-frequency microwave absorption performance, Carbon, 2025, 245, 120786.
[18] Haowei Zhou, Xiao Li,* Junyu Liu, Jinlin Zhang, Zhongming Liu, Moustafa Adel Darwish, M.M. Salem, Tao Zhou, Murat Yilmaz, Azim Uddin, Di Zhou,* Synergistic microwave absorption in MXene MnO2 composites achieved through interfacial engineering and controlled MnO2 morphology, Materials Today Physics, 2025, 57, 101822.
[19] Haowei Zhou, Xiao Li*, Zhaochen Xi, Man Li, Jieyan Zhang, Chao Li, Zhongming Liu, Moustafa Adel Darwish, Tao Zhou, Di Zhou*,Machine learning-driven interface engineering for enhanced microwave absorption in MXene films, Materials Today Physics, 2025, 51, 101640.
[20] Xin Wang, Kaiheng Zhang, Zhaochen Xi, Diming Xu,⁎ Wei Wang, Jian Bao, Kehong Zhou, Jun Li, Chao Liang, Tao Zhou, Da-Wei Liu, Song Xia, Kar BanTan, Di Zhou,⁎ Advancing Microwave Dielectric Properties by Structural Manipulation in BaZrO3-Ca(Mg1/3Nb2/3)O3 system, Applied Materials Today, 2025, 44, 102711.
[21]Zhen Fang, Kai-Heng Zhang, Wei Wang, Jian Bao, Guo-Qiang He, Jia-Pei Jiang, Hao-bo Zhai, Moustafa Adel Darwish, Tao Zhou, Di-Ming Xu, Song Xia, Kar Ban Tan*, Di Zhou*, Tunable Microwave Dielectric Properties of the (Ba₁₋ₓSrₓ)Li₂Ti₆O₁₄ Ceramics and Effects of BCB Addition on Performance, Applied Materials Today, 2025, 45, 102806.
[22] Wei Wang, Qingyao Wang, Diming Xu, Zhongqi Shi, Tiezhu Guo, Fayaz Hussain, Moustafa Adel Darwish, Tao Zhou, Yawei Chen, Qixin Liang, Meirong Zhang, and Di Zhou,* Temperature Stable (1-x)BaAl2Si2O8-xBa3V2O8 (0.2 ≤ x ≤ 0.5) Microwave Dielectric Composite Ceramics for LTCC Applications, Journal of the European Ceramic Society, 2025, 45, 117042.
[23] Diming Xu, Wei Wang, Ruitao Li, Zhen Fang, Shuwei Ma, Haobo Zhang, Tao Zhou, Wenfeng Liu, Di Zhou*, Highly Enhanced Dielectric Tunable Performance in Ba0.6Sr0.4TiO3 Ceramics via Li2ZnTi3O8 Addition Author links open overlay panel, Journal of the European Ceramic Society, 2026,46[2], 117775.
[24] Yulong Tian, Wei Wang, Xin Wang, Jie Li,* Di Zhou,* Influence of V substitutions on sintering behaviors and microwave dielectric properties of Ba4LiNb3O12 ceramic, Journal of the American Ceramic Society, 2025, 108[2], e20183.
[25] Wen-Bo Li, Li-Xia Pang*, Xiao-Long Wang, Wei-Guo Liu, Xiaogang Yao, Huixing Lin, Jin-Chao Miao, Di Zhou*, Low-permittivity and low dielectric loss in co-fired Na2O–Bi2O3–Ln2O3–MoO3 (Ln= Sm0.3Y0.7) microwave dielectric ceramics, Journal of the American Ceramic Society, 2025, 108[11], e70088.
[26] Diming Xu, Haowei Zhang, Lixia Pang, Fayaz Hussain, Tao Zhou, Shi-Kuan Sun, Zhijiao Chen and Di Zhou,* Rational Optimizations of High K Microwave Dielectric Ceramic Bi2(Li0.5Ta1.5)O7 towards LTCC Applications, Journal of the American Ceramic Society, 2025, 108[4], e20316.
[27] Ahmed Redwan Hazaa Alzakree, Chang-Hao Wang, Muhammad Shehbaz, Wei Wang, Moustafa Adel Darwish, Tao Zhou, Di-Ming Xu, Chao Du, and Di Zhou,⁎ Microwave dielectric properties of temperature-stable (Na0.5Bi0.5)MoO4–SrMoO4 ceramics sintered at ultra-low temperature,Journal of the American Ceramic Society, 2025, 108[7], e20504.
[28] Diming Xu, Haobo Zhang, Wei Wang, Ruitao Li, Shuwei Ma, Tao Zhou, Wenfeng Liu and Di Zhou,* Dielectric tunability of Ba0.6Sr0.4TiO3-Li2Mg3SnO6 ceramics with ultralow loss, Journal of the American Ceramic Society, 2025, 108:e20316.
[29] Chang-Hao Wang, Kai-Heng Zhang, Wei Wang, Jian Bao, Jia-Pei Jiang, Ke-Hong Zhou, Jun Li, Chao Liang, Da-Wei Liu, Moustafa Adel Darwish, Tao Zhou, Di-Ming Xu, Song Xia, Kar Ban Tan, and Di Zhou*, A comprehensive study on low temperature sintering and microwave/terahertz dielectric properties of BaO-P2O5 binary ceramics, Journal of Materials Chemistry C, 2025, 13, 14843-14855.
[30] Guoqiang He, Jinchao Miao, Fangfang Wu, Wei Wang, Jian Bao, Jia-Pei Jiang, Dawei Liu, Moustafa A. Darwish, Tao Zhou, Diming Xu, Song Xia, Kar Ban Tan and Di Zhou,* Advancements in Microwave Dielectric Ceramics with K20 for 5G/6G Communication Systems: A Review, Journal of Materials Chemistry C, 2025, 13, 15746.
[31] Xiangkun Li, Xiaogang Yao, Haiyi Peng,⁎ Huixing Lin, Wenfeng Liu, Tao Zhou, Diming Xu, Xiao Li, Di Zhou,⁎ Anisotropic mPPO/TiO2 composites with enhanced permittivity and thermal conductivity via planar and uniaxial orientation strategies, Journal of Alloys and Compounds, 2025, 1024, 180179.
[32] Azim Uddin* , Di Zhou*, Makhsudsho G. Nematov, Moustafa A. Darwish, Xiao Li, Mohamed M. Salem, Strategic dual-stratum microwire composites for effective electromagnetic shielding with low microwave reflectivity, Journal of Alloys and Compounds, 2025, 1030, 180880.
[33] Diming Xu, Zhibo Liu, Xiao Li, Maxim Avdeev, Ke-Hong Zhou, Jun Li, KarBan Tan, Tao Zhou, Di Zhou,⁎ Structural and magnetic properties of HoFeCuGe4O12 with a metamagnetic transition behavior, Materials Letters, 2025, 393, 138585.
[34] Kaiheng Zhang, Chao Du, Yuanxi Cao, Sen Yan, and Di Zhou*, Via-Free Dual-Polarized Angle-Selective Surface, IEEE Antennas and Wireless Propagation Letters, 2025, 24[8], 2317-2321.
[35] Diming Xu, Zhibo Liu, Xiao Li, Maxim Avdeev, Ke-Hong Zhou, Jun Li, KarBan Tang, Yin-Shan Meng,* Tao Zhou, Di Zhou,* From Antiferromagnetism to Field-Induced Ferromagnetism: A Cu2+-Governed Metamagnetic Landscape in RFeCuGe4O12 (R = Tm-Lu), Dalton Transactions, 2025,54, 12689-12699.
[36] Diming Xu, Haobo Zhang, Wei Wang, Ruitao Li, Tao Zhou, Wenfeng Liu, Di Zhou,* Dielectric tunability performance and structural evolution of Ba0.6Sr0.4TiO3-based ceramics by BaCuSi4O10-BaCuSi2O6 modification, Materials Letters, 2025, 401, 139286.
[37] Muhammad Shehbaz, Chao Du, Muhammad Wasif Niaz, Xiao-Gang Yao, Haiyi Peng, Hui-Xing Lin, Zhong-Qi Shi, Di-Ming Xu, Song Xia, Yong-Qiang Pang*, and Di Zhou*, All Ceramic Wideband Dielectric Patch Antenna Using Temperature-Stable High- Permittivity Ba4.5(Sm0.8La0.2)9Ti18O54 Microwave Dielectric Ceramic for 5G Applications, Advanced Engineering Materials, 2025, 27[7], 2402519.
[38] 刘阳，郭铁柱，郭艳，赵维琛，周迪*，二维Ba5Nb4O15提升聚合物基纳米复合薄膜的储能性能，《绝缘材料》，2025年，第58卷, 第4期：24-29。
[39] 何国强, 张恺恒, 王震涛, 包健, 席兆琛, 方振, 王昌昊, 王威, 王鑫, 姜佳沛, 李祥坤, 周迪*, Ba(Nd1/2Nb1/2)O3: 一种被低估的 K40 微波介质陶瓷, 无机材料学报，2025年，40 卷第 6 期, 639 -646。
[40] K.B. Tan*, P.Y. Tan, Y. Feng, C.C. Khaw, T.Z. Alvin Lim, M.M.A. Kechik, S.K. Chen, K.Y. Chan, M. Lu, J. Sun, D. Zhou, Optimising bismuth magnesium niobate pyrochlores as potential ceramic dielectrics: Reaction progression, phase equilibria and impedance properties, Ceramics International, 2025, 51, 24371–24385.
[41] K.B. Tan*, P.Y. Tan, Y. Feng, C.C. Khaw, V. Raman, H.C. Ananda Murthy, R. Balachandran, S.K. Chen, O.J. Lee, K.Y. Chan, D. Zhou, M. Lu,* Novel pyrochlores in the Bi2O3–MgO–Ta2O5 (BMT) system: Synthesis optimisation, phase equilibria and dielectric properties, Journal of Science: Advanced Materials and Devices, 2025, 10, 100866.
[42] Jing Li*, Lingling He, Chao Du, Weimin Xia, Di Zhou, Honeycomb LiFe5O8/PANI nanocomposites with enhanced microwave absorption performance, Ceramics International, 2025, 51, 7252-7262.
[43] Tallison Oliveira Abreu, Felipe Felix do Carmo, João Paulo Costa do Nascimento, Marcelo Antonio Santos da Silva, Roterdan Fernandes Abreu, Francisco Enilton Alves Nogueira, Franscisco Alekson Chaves Nobrega, Ronaldo Santos da Silva, Sergei V. Trukhanov, Di Zhou, Charanjeet Singh, Antonio Sergio Bezerra Sombra, High-sensitive upconversion optical thermometers derived of Y(Nb0.5Ti0.5)2O6:Er3+ /Yb3+ phosphors under 808 nm and 980 nm excitation, Applied Physics A, 2025, 131, 41.
[44] Wen-Bo Li, Li-Xia Pang*, Xiao-Long Wang, Wei-Guo Liu, Xiaogang Yao, Huixing Lin, Wen-Feng Liu, Di Zhou*, Microwave dielectric properties of Na2O–Ln2O3–MoO3–TiO2 (Ln = Nd, La and Ce) system with low-sintering temperature, Int J Appl Ceram Technol., 2025, 22, e14983.
[45] Xiao-Long Wang, Li-Xia Pang,⁎ Di Zhou,⁎ Yi Geng, Zhong-Nan Hu, Wen-Bo Li, High-performance of low-fired (1-x)Na0.5Y0.5MoO4-xLi0.5Y0.5MoO4 ceramics and microstrip bandpass filters designs for LTCC, Ceramics International, 2025, 51, 28812–28818.
[46] K. Firman, Y. Feng, T.Z. Alvin Lim, V. Raman, C.C. Khaw,* , S. Ghotekar, H.C. Ananda Murthy, K.Y. Chan, M. Lu, J. Sun, D. Zhou*, K.B. Tan, Optimising the structural and ionic conductivity of bismuth tantalate fluorites through rare-earth element doping, Journal of the Indian Chemical Society, 2025, 102, 101865.
[47] Li-Xia Pang,*, Hui Li, Wen-Bo Li, Qian Zhang, Ya-Wei Chen, Mei-Rong Zhang, Di-Ming Xu, Kar Ban Tan, Di Zhou*, Microwave dielectric properties and low-temperature sintering of (1-x) BaTi4O9-xBaMoO4 composite ceramics, Journal of Alloys and Compounds, 2025, 1045, 184690.
[48] Wen-Bo Li, Li-Xia Pang,* Hui Li, Wei Wang, Di-Ming Xu, Tao Zhou, Qi-Xin Liang, Mei- Rong Zhang, and Di Zhou*, Temperature-Stable (1−x)LaAlO3−xNa0.5La0.5TiO3 Perovskite Ceramics with Ultra-Low Microwave Dielectric Loss ACS Applied Electronic Materials, 2025, 7, 22, 10464–10470.
[49] Diana Estevez, Di Zhou, Xiao Li, Azim Uddin*, Internal Stress‑Driven Electromagnetic Shielding in Glass‑Coated Ferromagnetic Microwire Composites Journal of Electronic Materials, 2025, 54:9335–9345.

2024

[1] Ruitao Li, Diming Xu*, Chao Du, Qianqian Ma, Feng Zhang, Xu Liang*, Dawei Wang, Zhongqi Shi, Wenfeng Liu, and Di Zhou,* Giant dielectric tunability in ferroelectric ceramics with ultralow loss by ion substitution design, Nature Communications, 2024, 15, 3754.
[2] Fang-Fang Wu, Di Zhou,* Chao Du, Diming Xu, Zhong-Qi Shi, Moustafa Adel Darwish, Tao Zhou, Shi-Kuan Sun, Xiao-Gang Yao, Hui-Xing Lin, Mei-Rong Zhang, Qi-Xin Liang, Ya-Wei Chen, and Heli Jantunen,* A comprehensive study on crystal structure, phase compositions of the BiVO4-LaVO4 binary dielectric ceramic system and a typical design of Dielectric Resonator Antenna for C-band Applications, Applied Materials Today, 2024, 38, 102222.
[3] Yan Guo, Di Zhou*, Ruitao Li, Da Li, Weichen Zhao, Lixia Pang, Zhongqi Shi, Wenfeng Liu, Jinzhan Su, Tao Zhou, Guohua Chen, Novel relaxor ferroelectric BTWO nanofillers for improving the energy storage performance of polymer-based dielectric composites, Journal of Energy Storage, 2024, 76, 109585.
[4] Yan Guo, Weichen Zhao, Da Li, Yang Liu, Lixia Pang, Zhongqi Shi, Wenfeng Liu, Jinzhan Su, Guohua Chen, Di Zhou,* Trilayer structured ceramic/polymer nanocomposites with superior breakdown strength and discharged energy density, Composites Science and Technology, 2024, 248, 110477.
[5] Tiezhu Guo, Xiao Li, Haowei Zhou, Lixia Pang, Tao Zhou, Zhongqi Shi, Di Zhou,* Effect of large-sized hydrophilic polypyrrole on electrochemical properties of MXene films, Journal of Power Source, 2024, 593, 233978.
[6] Xiao Li, Haowei Zhou, Jinlin Zhang, Xinyue Zhang, Man Li, Jieyan Zhang, Moustafa Adel Darwish, Tao Zhou, Shi-Kuan Sun, Lei Xie,* Di Zhou,* Construction of shell-like carbon superstructures through anisotropically oriented self-assembly for distinct electromagnetic wave absorption, Journal of Materials Chemistry A, 2024, 12, 4057–4066.
[7] Xiangkun Li, Di Zhou*, Xiaogang Yao*, Haiyi Peng, Xingyu Tian, Zhongyuan Gu, Huixing Lin, Zhongqi Shi, Wenfeng Liu, Tao Zhou, Modified poly(phenylene oxide)/(CaSr)TiO3 composites with ultrahigh permittivity and low loss for microwave substrates, Journal of Alloys and Compounds, 2024, 970, 172533.
[8] Chang-Hao Wang, Zhong-Qi Shi, Wen-Feng Liu, Moustafa Adel Darwish, Tao Zhou, Ya-Wei Chen, Qi-Xin Liang, Mei-Rong Zhang, and Di Zhou,* Sintering behaviors and microwave dielectric properties of Ba3P4O13 ceramics, Materials Research Bulletin, 2024, 174, 112704.
[9] Xin Wang, Tao Zhou, Wei Wang, Zhaochen Xi, Diming Xu, Chao Du, Xiao-Gang Yao, Hui-Xing Lin, Huiqi Xia, Biaobing Jin, and Di Zhou,* Effect of B-site complex substitutions on orthorhombic distortions and microwave dielectric properties of Ca(Zr0.95Ti0.05)O3 perovskites, Journal of Materials Chemistry C, 2024, 12, 3124 - 3131.
[10] Sen Ren, Lixia Pang,* Xiaolong Wang, Zhen Fang, Di Zhou,* Yuanjie Zhao, Wenbo Li, Improvement of high-temperature energy storage properties of polyimide-based nanocomposites with sandwich structure, J Appl Polym Sci. 2024, 141, e54848.
[11] Yonghao Zhang, Yan Guo, Yang Liu, Zhongqi Shi, Wenfeng Liu, Jinzhan Su, Guohua Chen, and Di Zhou,* All-organic ArPTU/PEI composite dielectric films with high-temperature resistance and high energy storage density, Journal of Materials Chemistry C, 2024, 12, 4426-4432.
[12] Jinnan Liu, Da Li, Weichen Zhao, Diming Xu, Zhongqi Shi, Wenfeng Liu, Jinzhan Su, Tao Zhou*,Guohua Chen, andDi Zhou,* Excellent energy storage performance achieved in Sr(Sc0.5Nb0.5)O3 doped Bi0.5Na0.5TiO3-based lead-free relaxor ferroelectric ceramics, ACS Applied Energy Materials, 2024, 7, 2030–2038.
[13] Jing Li, Xiao Li, Li He, Huanhuan Guo, Weimin Xia, Bangyong Sun, Congjun Cao, Lijuan Sha, Di Zhou,* MoS2-based Nanocomposites for Microwave Absorption: A Review, ACS Applied Nano Materials, 2024, 7, 5761–5775.
[14] Chao Du, Huizhen Chen, Shaofei Wang, Yongqiang Pang, Tao Zhou, Song Xia, Di Zhou,* Dual-polarized angle-selective surface based on double-layer frequency selective surface, Appl. Phys. Lett., 2024, 124, 111701.
[15] Ahmed Redwan Hazaa Alzakree, Chang-Hao Wang, Muhammad Shehbaz, Wei Wang, Di-Ming Xu, Chao Du, Di Zhou,* Microwave dielectric properties of (Na0.5Bi0.5)MoO4–BaMoO4 composite ceramics with ultralow sintering temperature, Journal of the American Ceramic Society, 2024, 107, 4738–4746.
[16] Jia-Jia Ren, Di-Ming Xu, Qian-Qian Ma, Da Li, Wei-Chen Zhao, Zhen-Tao Wang, Tao Zhou, Wenfeng Liu, and Di Zhou,* Optimized energy storage performance in (Ba0.8Sr0.2)TiO3-based ceramics via Bi(Zn0.5Hf0.5)O3-doping, Journal of Materials Chemistry C, 2024, 12, 6239.
[17] Chao Du, Ziyan Bao, Hetuo Chen,* Guohong Zhou, Yongqiang Pang, Haiwen Liu, Huangfu Jiang, Tao Zhou, Song Xia, and Di Zhou,* A Wide-band High-gain Dielectric Resonator Antenna Based on Mullite Microwave Dielectric Ceramics, Journal of Applied Physics, 2024, 135, 144503.
[18] Jia-Pei Jiang, Chang-Hao Wang, Wei Wang, Zhong-Qi Shi, Xiao-Gang Yao, Hui-Xing Lin, Tao Zhou, Ya-Wei Chen, Qi-Xin Liang, Mei-Rong Zhang, Di Zhou*, Low-temperature sintering of (Co0.35Zn0.65)TiNb2O8 temperature-stable microwave dielectric ceramics with BaCu(B2O5) additions, Journal of the European Ceramic Society, 2024, 44, 6384–6389.
[19] 王震涛，李达，赵维琛，刘津男，徐谛明，周迪*, NaNbO3基无铅储能介质陶瓷研究进展, 硅酸盐学报, 2024, 52[4], 1460-1476.
[20] Li-Xia Pang, Zhen Fang, Di Zhou*, Wei Wang, Zhong-Qi Shi, Fayaz Hussain, Moustafa Adel Darwish, Tao Zhou, Shi-Kuan Sun, Qi-Xin Liang & Ya-Wei Chen, Sintering behaviors and microwave dielectric properties of BaO-MgO-SiO2 ternary ceramics, International Journal of Applied Ceramic Technology, 2024, 21, 3652–3659.
[21] Yu Lou, Wei Wang, Di-Ming Xu, Chao Du, Xin Wang, Fayaz Hussain, Moustafa Adel Darwish, Tao Zhou, Ya-Wei Chen, Qi-Xin Liang, Mei-Rong Zhang, Yong-Qiang Pang, & Di Zhou*, Effect of LiF and LBSCA glass on the microwave dielectric properties of 0.5BaCuSi4O10-0.5BaCuSi2O6-based ceramics for LTCC applications, Journal of the American Ceramic Society, 2024, 107, 6964–6973.
[22] Xiao-Long Wang, Li-Xia Pang*, Di Zhou*, Wen-Bo Li, Sen Ren, Wei-Guo Liu, Microwave dielectric properties of (1-x)Na0.5Y0.5MoO4-xNa0.5Bi0.5MoO4 ceramics for LTCC applications, Journal of the European Ceramic Society, 2024, 44, 7623–7629.
[23] Sen Ren, Shihao Yuan, Mingkun Huang, Lixia Pang, Wenbo Li, Xiaolong Wang, Di Zhou*, Yuanjie Zhao, Cost-Effective Strategy for high-temperature energy storage performance of polyimide nanocomposite films, Journal of Energy Storage, 2024, [95], 112524.
[24] Shehbaz, Muhammad; Du, Chao; Li, Rui-Tao; Wang, wei; Alzakree, Ahmed Redwan Hazaa; Yao, Xiaogang; Peng, Haiyi; Lin, Huixing; Shi, Zhong-Qi; Xu, Diming; Xia, Song; Pang, Yongqiang; Zhou Di*, Millimeter wave dielectric resonator antenna using high quality factor temperature stable dielectric ceramic composite K18 for 5G applications, ACS Applied Electronic Materials, 2024, 6, 6120-6130.
[25] Chang-Hao Wang, Wei Wang, Di-Ming Xu, Ahmed Redwan Hazaa Alzakree, Fayaz Hussain, Moustafa Adel Darwish, Tao Zhou, Ya-Wei Chen, Qi-Xin Liang, Mei-Rong Zhang, Yaguang Wu, Di Zhou*, Low temperature sintering and improvement of temperature Stability of Ba3P4O13 microwave dielectric ceramics by BCB additions, Materials Research Bulletin, 2024, 179, 112964.
[26] Wei Wang, Xin Wang, Jian Bao, Jiapei Jiang, Zhen Fang, Biaobing Jin, Zhongqi Shi, Moustafa Adel Darwish, Yawei Chen, Qixin Liang, Meirong Zhang, Diming Xu, Chao Du, Di Zhou*, Low-permittivity BaCuSi4O10-based dielectric Ceramics: An available solution to connect low temperature cofired ceramic technology and millimeter-wave communications, Chemical Engineering Journal, 2024, 494, 153172.
[27] Zhentao Wang, Da Li, Wenyuan Liu, Xu Liang, Weichen Zhao, Jinnan Liu, Jiajia Ren, Tao Zhou, Diming Xu, Wenfeng Liu and Di Zhou*, Improved energy storage properties achieved in NaNbO3-based relaxor antiferroelectric ceramics via anti-parallel polar nanoregion design, Journal of Materials Chemistry A, 2024, 12, 19551–19558.
[28] Zi-Yang Liu, Wei Wang, Di-Ming Xu, Chao Du, Xin Wang, Guo-Qiang He, Fayaz Hussain, Tao Zhou, Biao-Bing Jin, Ke-Hong Zhou, Jun Li, Chao Liang, Di Zhou*, Microwave dielectric properties, vibrational spectrum, and antenna design of a novel melilite-type Ba2CoSi2O7 ceramic, Journal of the American Ceramic Society, 2024, 107, 8342–8353.
[29] Jian Bao, Kai-Heng Zhang, Wei Wang, Zi-Yang Liu, Zhen Fang, Xin Wang, Chang-Hao Wang, Yu-Chun Li, Guo-Qiang He, Tao Zhou and Di Zhou*, A series of ultra-low permittivity ALaP4O12 (A=Li, Na, K) metaphosphate microwave dielectric ceramics for ultra-wideband dielectric resonant antenna application, ACS Applied Materials & Interfaces, 2024, 16, 58898−58911.
[30] Chao Du, Zhiji Wang, Hetuo Chen, Guohong Zhou, Shaofei Wang, Song Xia, Di Zhou,* Preparation of temperature-stable 0.8MgTiO3-0.2Mg2SiO4-0.06CaTiO3 microwave dielectric ceramics for unilateral radiating dielectric resonator antenna without ground plane, Journal of Applied Physics, 2024, 136, 214501.
[31] Man Li, Xiao Li*, Jieyan Zhang, Haowei Zhou, Zhenfa Yu, Chao Li, Moustafa Adel Darwish, Tao Zhou, Shi-Kuan Sun, Di Zhou*, Cavity-modulated visualization of dual magnetic coupling behavior for multifunctional Co/DMAOP composites, Chemical Engineering Journal, 2024, 501, 157694.

2023

[1] Weichen Zhao, Diming Xu*, Da Li, Max Avdeev, Hongmei Jing, Mengkang Xu, Yan Guo, Dier Shi, Tao Zhou, Wenfeng Liu, Dong Wang*, Di Zhou*,Broad-high operating temperature range and enhanced energy storage performances in lead-free ferroelectrics, Nature Communications, 2023, 14:5725.
  [2] Ruitao Li, Diming Xu, Max Avdeev, Lei Zhang, Xinfeng Chen, Gaoyang Gou, Dong Wang, Wenfeng Liu, Di Zhou*, Ultralow loss and high tunability in a non-perovskite relaxor ferroelectric, Advanced Functional Materials, 2023, 33[3], 2210709.
  [3] Muhammad Shehbaz, Chao Du, Di Zhou*, Song Xia, Zhuo Xu, Recent Progress in Dielectric Resonator Antenna: Materials, Designs, Fabrications and Their Performance, Applied Physics Reviews, 2023, 10, 021303.
  [4] Muhammad Shehbaz, Chao Du, Ahmed Redwan Hazaa Alzakree, Wei Wang, Song Xia, Zhong-Qi Shi, Tao Zhou, Qi-Xin Liang, Mei-Rong Zhang and Di Zhou*, Design and Fabrication of Wideband Dielectric Resonator Antenna Using Low Loss Ultra-low Sintering Temperature Li6B4O9 Microwave Dielectric Ceramic for Wireless Communication Applications, Advanced Materials Technologies, 2023, 8[23], 2301060.
  [5] Tiezhu Guo, Min Gao, Shungui Deng, Jonathan Avaro, Jakob Heier*, Di Zhou, Jing Wang and Chuanfang (John) Zhang*, Large-area Smooth metallic MXene films enabled by scalable slot-die coating of aqueous inks, Advanced Functional Materials, 2023, 33[15], 2213183.
  [6] Tiezhu Guo, Di Zhou*,, Shungui Deng, Mohammad Jafarpour, Jonathan Avaro, Antonia Neels, Jakob Heier*, Chuanfang (John) Zhang, Rational Design of Ti3C2Tx MXene Inks for Highly Aligned, Transparent, Metallic Films, ACS Nano, 2023, 17, 4, 3737–3749.
  [7] Da Li, Diming Xu,* Weichen Zhao, Max Avdeev, Hongmei Jing, Yan Guo, Tao Zhou, Wenfeng Liu, Dong Wang* and Di Zhou*, A high-temperature performing and near-zero energy loss lead-free ceramic capacitor, Energy & Environmental Science, 2023,16, 4511-4521.
  [8] Da Li, Di Zhou*, Dong Wang,* Weichen Zhao, Yan Guo, Zhongqi Shi, Tao Zhou, Shi-Kuan Sun, Charanjeet Singh, Sergei Trukhanov, Antonio Sergio Bezerra Sombra, Lead-Free Relaxor Ferroelectric Ceramics with Ultrahigh Energy Storage Densities via Polymorphic Polar Nanoregions Design, Small, 2023, 19[8] 2206958.
  [9] Fang-Fang Wu, Di Zhou*, Chao Du, Di-Ming Xu, Rui-Tao Li, Zhong-Qi Shi, Moustafa Adel Darwish, Tao Zhou, and Heli Jantunen*, Design and Fabrication of a Satellite Communication Dielectric Resonator Antenna with Novel Low Loss and Temperature Stabilized (Sm1−xCax)(Nb1−xMox)O4 (x=0.15−0.7) Microwave Ceramics, Chemistry of Materials, 2023, 35, 104-115.
  [10] Di Zhou*, Ling Zhang, Di-Ming Xu, Feng Qiao, Xiaogang Yao, Huixing Lin, Wenfeng Liu, Li-Xia Pang, Fayaz Hussain, Moustafa Adel Darwish, Tao Zhou, Yawei Chen, Qixin Liang, Meirong Zhang, Ian M. Reaney*, Novel Method to Achieve Temperature Stable Microwave Dielectric Ceramics: A Case in Fergusonite Structured NdNbO4 System, ACS Applied Materials & Interfaces, 2023, 15, 19129–19136.
  [11] Xiao Li, Diming Xu, Di Zhou*, Shengzhao Pang, Chao Du, Moustafa Adel Darwish, Tao Zhou, Shi-Kuan Sun, Vertically stacked heterostructures of MXene/rGO films with enhanced gradient impedance for high-performance microwave absorption, Carbon, 2023, 208, 374-383.
  [12] Xiao Li, Diming Xu, Di Zhou*, Shengzhao Pang, Chao Du, Moustafa Adel Darwish, Tao Zhou, Shi-Kuan Sun, Magnetic array vertically anchored on flexible carbon cloth with “magical angle” for the increased effective absorption bandwidth and improved reflection loss simultaneously, Carbon, 2023, 210, 118046.
  [13] Xiao Li, Diming Xu, Di Zhou*, Hu Nan, Shengzhao Pang, Moustafa Adel Darwish, Tao Zhou, Shi-Kuan Sun, Introducing large-radius elements into layered perovskite for low-voltage lithium storage, Journal of Materials Chemistry A, 2023, 11, 14249.
  [14] Guo Yan, Di Zhou*, Li Da; Zhao Weichen; Wang Yifei; Pang Li-Xia; Shi Zhongqi; Zhou Tao; Sun Shi-Kuan; Singh Charanjeet; Trukhanov Sergei; Sombra Antonio; Chen Guohua, Improved energy storage performance of sandwich-structured P(VDF-HFP)-based nanocomposites by the additions of inorganic nanoparticles, Journal of Materials Chemistry C, 2023, 11, 6999-7009.
  [15] Chao Du, Xiang-Kun Li, Di Zhou*, Shao-Fei Wang, Rui-Tao Li, Xiao-Gang Yao, Hui-Xing Lin, Hai-Yi Peng,* Tao Zhou, Shi-Kuan Sun, Song Xia and Zhuo Xu, Fabrication of High Radiation Efficiency Dielectric Resonator Antenna Arrays from Temperature Stable 0.8Zn2SiO4-0.2TiO2 Microwave Dielectric Ceramic, Advanced Materials Technologies, 2023, 8[10], 2201985.
  [16] Wen-Yi Li, Di Zhou*, Da Li, Yan Guo, Wei-Chen Zhao, Li-Xia Pang , Shi-Kuan Sun, High Energy Storage Density in Nd(Zn2/3Nb1/3)O3-Doped BiFeO3-BaTiO3 Ceramics, Advanced Electronic Materials, 2023, 9, 2200930.
  [17] Jiajia Ren; Di Zhou*, Wenbo Li; Da Li; Yan Guo; Tao Zhou; Shikuan Sun, Improved Energy Storage Density performance of the (1-x) [0.88BaTiO3-0.12Bi(Li0.5Nb0.5)O3]-x(0.8BaTiO3-0.2SrTiO3) Lead-Free Ceramics, Materials Research Bulletin, 2023, 161, 112157.
  [18] Jia-Jia Ren, Di Zhou*, Da Li, Yan Guo, Wei-Chen Zhao, Tao Zhou, and Li-Xia Pang, Dielectric and Energy Storage Properties of Layer-Structured Ban−3Bi4TinO3n+3 (n =4~7) Ferroelectrics, Advanced Engineering Materials, 2023, 25, 2201677.
  [19] Jia-Jia Ren, Di-Ming Xu, * Da Li, Wei-Chen Zhao, Meng-Kang Xu, Zhong-Qi Shi, Tao Zhou, Hui-Xing Lin and Di Zhou*,Significantly enhanced energy storage density in lead-free barium strontium titanate-based ceramics through a cooperative optimization strategy, J. Mater. Chem. C, 2023,11, 16739-16747
  [20] Yan Guo, Di Zhou*, Da Li, Weichen Zhao, LiXia Pang, Zhongqi Shi, Wenfeng Liu, Jinzhan Su, Tao Zhou and Shikuan Sun, Effect of Inorganic Nanoparticles on Energy Storage Properties of P(VDF-HFP)-based Nanocomposites, Advanced Engineering Materials, 2023, 25, 2300070.
  [21] 王威，张玲，吴亚光，乔峰，史忠旗，刘文凤，周迪*，微波毫米波用低介电常数低温共烧陶瓷研究进展，硅酸盐学报，2023，51[4]，934-948。
  [22] Wei Wang, Di-Ming Xu, Di Zhou*, Chao Du, Xin Wang, Hong-Song Qiu, Biao-Bing Jin, Zhong-Qi Shi, Fayaz Hussain, Moustafa Adel Darwish, Tao Zhou, Ya-Wei Chen, Qi-Xin Liang & Mei-Rong Zhang, β-Ga2O3: Ultralow loss and low permittivity dielectric ceramics for high-frequency packaging substrate, Inorganic Chemistry Frontiers, 2023, 10, 3723–3729.
  [23] Wang, Wei; Shehbaz, Muhammad; Wang, Xin; Du, Chao; Xu, Diming; Shi, Zhong-Qi; Darwish, Moustafa Adel; Qiu, Hongsong; Jin, Biao-Bing; Zhou, Tao; Chen, Yawei; Liang, Qixin; Zhang, Meirong; Di Zhou*, Low Permittivity and Low Temperature Co-Fired BaSO4-BaF2 Microwave Dielectric Ceramics for High Reliability Packaged Electronics, ACS Applied Materials & Interfaces, 2023, 15, 51453−51461.
  [24] Diming Xu, Haowei Zhang, Lixia Pang, Fayaz Hussain, Tao Zhou, Shi-Kuan Sun, Zhijiao Chen and Di Zhou*, Novel B-site Scheelite Structure Ceramic Bi(Ge0.5Mo0.5)O4 and Its Dielectric Properties, Journal of the American Ceramic Society, 2023, 106[11], 6675-6683.
  [25] Jia-Pei Jiang, Di Zhou*,Wei Wang, Chang-Hao Wang, Zhong-Qi Shi, Wen-Feng Liu, Tao Zhou, Ya-Wei Chen, Qi-Xin Liang, and Mei-Rong Zhang, Crystal structure and microwave dielectric properties of temperature stable (CoxZn1-x)TiNb2O8 ceramics, Journal of the American Ceramic Society, 2023, 106, 5868-5876.
  [26] Zhenting Chen, Chao Du, Jie Liu, Di Zhou*, and Zhongxiang Shen, Design Methodology of Dual-Polarized Angle Selective Surface Based on Three-Layer Frequency Selective Surfaces, IEEE Transactions on Antennas and Propagation, 2023, 71[11], 8704-8713.
  [27] Li-Xia Pang*, Sen Ren, Xiao-Long Wang, Di Zhou*, Wei-Guo Liu, Charanjeet Singh, Antonio Sergio Bezerra Sombra, and Moustafa Adel Darwish, High Energy Storage Density and Efficiency of the xBi(Mg2/3Nb1/3)O3-(1-x)(Ba0.8Sr0.2)TiO3 (0.08 ≤ x ≤ 0.14) Lead-free Perovskite Structured Ceramics, Advanced Engineering Materials, 2023, 2300321.
  [28] Xiaolong Wang, Lixia Pang*, Di Zhou*, Zhen Fang, Sen Ren, and Weiguo Liu, Microwave dielectric properties of tetragonal scheelite-structured (NaY)1/2MoO4 ceramics, International Journal of Applied Ceramic Technology, 2023, 20[4], 2586-2592.
  [29] Zhen Fang, Li-Xia Pang*, Di Zhou*, Low-loss and temperature stable (1-x)Ba3P2O8-xMg2B2O5 composite ceramics with low sintering temperature, Journal of the European Ceramic Society, 2023, 43[5], 1972-1977.
  [30] Zhen Fang, Li-Xia Pang*, Di Zhou*, Xiao-Long Wang, Sen Ren, and Wei-Guo Liu, Phase compositions and microwave dielectric characteristics of xMg2B2O5-(1-x)Ba3V2O8 (0.5≤x≤0.7) ceramics, Journal of Alloys and Compounds, 2023, 933, 167662.
  [31] Li-Xia Pang, Di Zhou*, Xiao-Gang Yao, Hui-Xing Lin, Chen Chen, Zhong-Qi Shi, Fayaz Hussain, Moustafa Adel Darwish, Tao Zhou, Shi-Kuan Sun, Qi-Xin Liang, Ya-Wei Chen, Phase transitions and microwave dielectric behaviors of the (Bi1-xLi0.5xY0.5x)(V1-xMox)O4 ceramics, Journal of the American Ceramic Society, 2023, 106[6] 3455-3461.
  [32] Xiao-Long Wang, Li-Xia Pang*, Di Zhou*, Zhen Fang, Sen Ren, Wei-Guo Liu, Microwave dielectric properties of (KY)1/2MoO4 ceramics with ultra-low sintering temperature, Materials Today Communications, 2023, 34, 105289.
  [33] Ahmed Maher Henaish a b, Moustafa A. Darwish a, Osama M. Hemeda, Ilya A. Weinstein, Tarek S. Soliman, Alex V. Trukhanov, Sergei V. Trukhanov, Di Zhou, Ali M. Dorgham, Structure and optoelectronic properties of ferroelectric PVA-PZT nanocomposites, Optical Materials, 2023, 138, 113402.
  [34] Fei Shang*, Juwen Wei, Yifa Deng, Guixiong Tang, Jiwen Xu*, Di Zhou,, Huarui Xu,* Guohua Chen, A novel route to produce BaTiO3 glass-ceramics with nanosized cubic BaTiO3 phase precipitating for high energy-storage applications, Journal of the European Ceramic Society, 2023, 43, 3307-3317.
  [35] Charanjeet Singh, Jasbir Singh, J. E. V. de Morais, R. G. M. Oliveira, F. F. Do Carmo, M. A. S. Silva, A. S. B. Sombra, Souad Ammar‑Merah, Rajat Joshi, Di Zhou, Sergei Trukhanov, Larissa Panina, Alex Trukhanov, Structural, electrical, and impedance properties of Co and Sn doped Ba0.5Sr0.5Fe12‑2xO19 hexaferrite ceramics (0 ≤ x ≤ 1) and their evaluation for antenna application, Applied Physics A, 2023, 129, 550.
  [36] M. M. Salem, K. A. Darwish, O. M. Hemeda, M. I. Abdel Ati, Anwer S. Abd El‑Hameed, Di Zhou, Moustafa A. Darwish, Exploring the promising frontiers of barium hexaferrite and barium titanate composites for electromagnetic shielding applications, Applied Physics A, 2023, 129:638.
  [37] Mu Li, Ying Tang,* Huaicheng Xiang, Jie Li, Di Zhou, Liang Fang,* Combined effect of rattling and compression on the microwave dielectric properties of B-site 1:3 ordered Li6A7Ti11O32 (A = Zn, Mg) spinels, Ceramics International, 2023, 49, 8754–8761.
  [38] Sen Ren, Yuanjie Zhao, Li-Xia Pang,* Xiaolong Wang, Di Zhou*, Wenbo Li, and Zhen Fang, Polyimide Nanocomposites Filled with SiO2 Nanoparticles of Different Sizes for High-Temperature Energy Storage, ACS Appl. Nano Mater. 2023, 6, 24, 23332–23343.
  [39] 任森, 庞利霞,* 周迪, 郭艳, 王晓龙, 方振, 袁世豪，储能聚合物复合方式的研究进展，功能材料，2023 年第9 期(54) 卷，09070-09079。
  [40] Lubing Li, Lei Zhang, Tianyu Zhai, Sheng Yang, Weiding Wang, Di Zhou, Jinzhan Su,* and Liejin Guo, Structurally Ordered PtNi Intermetallic Nanoparticles as Efficient and Stable Cathode Catalysts for Proton Exchange Membrane Fuel Cells, Chemistry—A European Journal, 2023, 29, e202300099.
  [41] K. A. Darwish, O. M. Hemeda, M. I. Abdel Ati, Anwer S. Abd El‑Hameed, Di Zhou, Moustafa A. Darwish, M. M. Salem,* Synthesis, characterization, and electromagnetic properties of polypyrrole–barium hexaferrite composites for EMI shielding applications, Applied Physics A, 2023, 129:460.
  [42] Marwa M. Hussein, Samia A. Saafan, H.F. Abosheiasha, Anwer S. Abd El-Hameed, Di Zhou, M.M. Salem, Moustafa A. Darwish,* Design, characterization, fabrication, and performance evaluation of ferroelectric dielectric resonator antenna for high-speed wireless communication applications, Journal of Alloys and Compounds, 2023, 968, 172170.
  [43] Enas H. El-Ghazzawy, Hesham M.H. Zakaly*, Albandari W. Alrowaily, Samia A. Saafan, Antoaneta Ene,*, Nagat M. Abo-aita, Moustafa A. Darwish, Di Zhou, Ahmed S. Atlam, Delving into the properties of nanostructured Mg ferrite and PEG composites: A comparative study on structure, electrical conductivity, and dielectric relaxation, Heliyon, 2023, 9, e19745.
  [44] Fuzhou Song, Xiangyu Wang, Jiqing Lv, Zhongfen An, Yue Xu, Lingcui Zhang, Hai Guo, Di Zhou, Huanfu Zhou, Feng Shi*, Lattice vibrational characteristics and structure-property relationships of SrWO4- x wt.% LiF (x = 0.5–3.0) microwave dielectric ceramics, Ceramics International, 2023, 49, 9338–9345.

2022

[1] Da Li, Di Zhou,* Dong Wang,* Weichen Zhao, Yan Guo, Zhongqi Shi, Improved Energy Storage Properties Achieved in (K,Na)NbO3‑Based Relaxor Ferroelectric Ceramics via a Combinatorial Optimization Strategy, Advanced Functional Materials,2022, 32[15], 2111776.
[2] Pengjian Wang, Yan Guo, Di Zhou,* Da Li, Lixia Pang, Wenfeng Liu, Jinzhan Su, Zhongqi Shi, Shikuan Sun, High-Temperature Flexible Nanocomposites with Ultra-High Energy Storage Density by nanostructured MgO fillers, Advanced Functional Materials,2022, 32[31], 2204155.
[3] Tiezhu Guo, Di Zhou*, Lixia Pang, Shikuan Sun, Tao Zhou, and Jinzhan Su, Perspectives on Working Voltage of Aqueous Supercapacitors, Small, 2022, 18[16], 2106360.
[4] Yan Guo, Di Zhou,* Ran Xu, Qingshan Zhu, Da Li, WeiChen Zhao, LiXia Pang, Yifei Wang, Wenfeng Liu, Jinzhan Su, Tao Zhou and Shikuan Sun, Enhancement in the energy storage performance of P(VDF-HFP)-based composites by adding PLZST inorganic nanoparticles, Journal of Materials Chemistry A, 2022, 10, 22058-22066..
[5] Fang-Fang Wu, Di Zhou,* Chao Du, Di-Ming Xu,* Rui-Tao Li, Ling Zhang, Feng Qiao, Zhong-Qi Shi, Moustafa Adel Darwish, Tao Zhou, Heli Jantunen, and Ian M. Reaney*, Design and Fabrication of a C-band Dielectric Resonator Antenna with Novel Temperature Stable Ce(Nb1-xVx)NbO4 (x = 0 - 0.4) Microwave Ceramics, ACS Applied Materials & Interfaces, 2022, 14, 48897-48906.
[6] Wu, Fangfang; Zhou, Di*; Du, Chao; Jin, Biao-Bing; Li, Chun; Qi, Zeming; Sun, Shikuan; Zhou, Tao; Li, Qiang; Zhang, Xiuqun, Design of a Sub-6 GHz Dielectric Resonator Antenna with Novel Temperature Stabilized (Sm1-xBix)NbO4 (x=0-0.15) Microwave Dielectric Ceramics, ACS Applied Materials & Interfaces, 2022, 14, 5, 7030–7038.
[7] Shu-Zhao Hao,Di Zhou*, Li-Xia Pang, Ming-Zhao Dang,* Shi-Kuan Sun, Tao Zhou, Sergei Trukhanov, Alex Trukhanov, Antonio Sergio Bezerra Sombra, Qiang Li, Xiu-Qun Zhang, Song Xia, Moustafa Adel Darwish, Ultra-low temperature co-fired ceramics with adjustable microwave dielectric properties in Na2O-Bi2O3-MoO3 ternary system: A comprehensive study, Journal of Materials Chemistry C, 2022, 10, 2008–2016.
[8] Tiezhu Guo, Di Zhou,* Lixia Pang, Moustafa Adel Darwish, Zhongqi Shi, Sandwich-type macroporous Ti3C2Tx MXene frameworks for supercapacitor electrode, Scripta Materialia, 2022, 213, 114590.
[9] Chao Du, Di Zhou*, Rui-Tao Li, He-Tuo Chen*, Guo-Hong Zhou, Bin Tang, Moustafa Adel Darwish, Song Xia and Zhuo Xu, Fabrication of Wideband Low-Profile Dielectric Patch Antennas from Temperature Stable 0.65CaTiO3-0.35LaAlO3 Microwave Dielectric Ceramic, Advanced Electronic Materials, 2022, 2101414.
[10] Chao Du, Di Zhou*, Lin-Ping Feng, Tan-Tan Zhao, He-Tuo Chen, Hai-Wen Liu, Moustafa A. Darwish, Song Xia, and Zhuo Xu, Wideband Low-Profile H-shaped Dielectric Patch Antennas based Microwave Dielectric Ceramics, Applied Physics Letters, 2022, 120, 223301.
[11] Fang-Fang Wu, Di Zhou,* Song Xia, Ling Zhang, Feng Qiao, Li-Xia Pang, Shi-Kuan Sun, Tao Zhou, Charanjeet Singh, Sergei Trukhanov, Alex Trukhanov, Antonio Sergio Bezerra Sombra, Moustafa Adel Darwish, Ian M. Reaney, Low sintering temperature, temperature-stable scheelite structured Bi[V1-x(Fe1/3W2/3)x]O4 microwave dielectric ceramics, Journal of the European Ceramic Society, 2022, 42, 5731–5737.
[12] Lixia Pang*, Xiaolong Wang, Di Zhou*, Zhen Fang, Xingyu Tian, Weiguo Liu, Zeming Qi, Song Xia, Moustafa Adel Darwish, Microwave dielectric properties and vibrational spectra of (Na0.5xLa1-0.5x)(Nb1-xMox)O4 ceramics with scheelite structures, Journal of the European Ceramic Society, 2022, 42, 5726–5730.
[13] Jing Li, Di Zhou*, Maosen Fu, Pengjian Wang, Jinzhan Su, Shikuan Sun, Tao Zhou, Zhuo Xu, Coral-Like Polypyrrole/LiFe5O8/MoS2 Nanocomposites for High-Efficiency Microwave Absorbers, ACS Applied Nano Materials, 2022, 5, 7944−7953.
[14] Tiezhu Guo, Di Zhou*, Chuanfang Zhang,* Perspectives on electrochemical nitrogen fixation catalyzed by two-dimensional MXenes, Materials Reports: Energy, 2022, 2, 100076..
[15] 郭铁柱，周迪，张传芳*，MXenes胶体氧化的调控策略及其对超级电容器性能的影响，储能科学与技术，2022年，第11卷，第4期，1165-1174.
[16] F. G. Agayev, S. V. Trukhanov, An. V. Trukhanov, S. H. Jabarov, G. Sh. Ayyubova, M. N. Mirzayev, E. L. Trukhanova, D. A. Vinnik, A. L. Kozlovskiy, M. V. Zdorovets, A. S. B. Sombra, Di Zhou, R. B. Jotania, C. Singh, A. V. Trukhanov, Study of structural features and thermal properties of barium hexaferrite upon indium doping, Journal of Thermal Analysis and Calorimetry (2022) 147:14107–14114.
[17] Ashraf M. Semaida, Moustafa A. Darwish, Mohamed M. Salem, Di Zhou, Tatiana I. Zubar, Sergei V. Trukhanov,* Alex V. Trukhanov, Vladimir P. Menushenkov and Alexander G. Savchenko, Impact of Nd3+ Substitutions on the Structure and Magnetic Properties of Nanostructured SrFe12O19 Hexaferrite, Nanomaterials, 2022, 12, 3452
[18] Liting Wei, Mingyue Du, Rui Zhao, Fei Lv, Lubing Li, Lei Zhang, Di Zhou and Jinzhan Su*, High-valence Mo doping for highly promoted water oxidation of NiFe (oxy)hydroxide, Journal of Materials Chemistry A, 2022, 10, 23790-23798.
[19] Reda E. El-Shater, Hassan El Shimy, Samia A. Saafan, Moustafa A. Darwish, Di Zhou, Alex V. Trukhanov, Sergei V. Trukhanov, Fatma Fakhry, Synthesis, characterization, and magnetic properties of Mn nanoferrites, Journal of Alloys and Compounds, 2022, 928, 166954.
[20] Moustafa A. Darwish, Tatiana I. Zubar*, Oleg D. Kanafyev, Di Zhou, Ekaterina L. Trukhanova, Sergei V. Trukhanov*, Alex V. Trukhanov and Ahmed Maher Henaish, Combined Effect of Microstructure, Surface Energy, and Adhesion Force on the Friction of PVA-Ferrite Spinel Nanocomposites, Nanomaterials, 2022, 12, 1998.
[21] Shaimaa A. Habib, Samia A. Saafan, Talaat M. Meaz, Moustafa A. Darwish, Di Zhou, Mayeen U. Khandaker, Mohammad A. Islam, Hamidreza Mohafez*, Alex V. Trukhanov, Sergei V. Trukhanov,* and Maha K. Omar, Structural, Magnetic, and AC Measurements of Nanoferrites-Graphene Composites, Nanomaterials, 2022, 12, 931
[22] Reda E. El-Shater, Ahmed S. Atlam, M.K. Elnimr, S.T. Assar, D.I. Tishkevich, T.I. Zubar, S.V. Trukhanov, A.V. Trukhanov*, Di Zhou, Moustafa A. Darwish, AC measurements, impedance spectroscopy analysis, and magnetic properties of Ni0.5Zn0.5Fe2O4/BaTiO3 multiferroic composites, Materials Science and Engineering B, 2022, 286, 116025.
[23] Xiangyu Wang, Jiqing Lv, Yue Xu, Lingcui Zhang, Yan Shen, Huanfu Zhou, Di Zhou, Kaixin Song, Hai Guo, Feng Shi*, Dielectric responses and structure-property relationships of Ca1-xBaxWO4 composite microwave dielectric ceramics，Journal of Alloys and Compounds, 2022, 925, 166669.
[24] Luke Wang, Xiangyu Wang, Danhui Cheng, Yue Xu, Huanfu Zhou, Di Zhou, Kaixin Song, Hai Guo, Feng Shi*, and Jing Wang, Crystal structure, lattice vibrational characteristics, and dielectric properties of phase pure LiCoPO4 ceramic, J Mater Sci: Mater Electron, 2022, 33:15263–15271.
[25] Vitalii Alexandrovich Turchenko, Sergei Valentnovich Trukhanov, Vladmir Grigor'evich Kostishin, Francua Damay, Florance Porcher, Denis Sergeevich Klygach, Maxim Grigor'evich Vakhitov, Lyudmila Yur'evna Matzui, Olena Sergeevna Yakovenko, Bernat Bozzo, Ignasi Fina, Munirah Abdullah Almessiere, Yassine Slimani, Abdulhadi Baykal, Di Zhou, Alex Valentinovich Trukhanov, Impact of In3+ cations on structure and electromagnetic state of M−type hexaferrites, Journal of Energy Chemistry, 2022, 69, 667–676.
[26] Maha Mostafa, Oday Saleh, Ahmed Maher Henaish, Samir Ali Abd El-Kaream, Ryad Ghazy, Osama M. Hemeda, Ali M. Dorgham, Hanan Al-Ghamdi, Aljawhara H. Almuqrin, M. I. Sayyed, Sergei V. Trukhanov, Ekaterina L. Trukhanova*, Alex V. Trukhanov, Di Zhou and Moustafa A. Darwish, Structure, Morphology and Electrical Magnetic Properties of Ni-Mg Nano-Ferrites from a New Perspective, Nanomaterials, 2022, 12, 1045.
[27] Shaimaa A. Habib, Samia A. Saafan, Talaat M. Meaz, Moustafa A. Darwish, Di Zhou, Mayeen U. Khandaker, Mohammad A. Islam, Hamidreza Mohafez*, Alex V. Trukhanov, Sergei V. Trukhanov* and Maha K. Omar, Structural, Magnetic, and AC Measurements of Nanoferrites Graphene Composites, Nanomaterials, 2022, 12, 931.
[28] Ying Tang, Shiyao Shen, Jie Li*, Xiangguang Zhao, Huaicheng Xiang, Heping Su*, Di Zhou, Liang Fang, Characterization of structure and chemical bond in high-Q microwave dielectric ceramics LiM2GaTi2O8 (M = Mg, Zn), Journal of the European Ceramic Society, 2022, 42[11], 4573-4579.
[29] Weichao Lou, Kaixin Song*, Fayaz Hussain, Amir Khesro, Jianwei Zhao, Hadi Barzegar Bafrooei, Tao Zhou, Bing Liu, Minmin Mao, Kuiwen Xu, Ehsan Taheri-nassaj, Di Zhou, Shaojin Luo, Shikuan Sun, Huixing Lin, Dawei Wang, Microwave dielectric properties of Mg1.8R0.2Al4Si5O18 (R=Mg, Ca, Sr, Ba, Mn, Co, Ni, Cu, Zn) cordierite ceramics and their application for 5G microstrip patch antenna, Journal of the European Ceramic Society, 2022, 42, 2254–2260
[30] Weichao Lou, Minmin Mao, Kaixin Song*, Kuiwen Xu, Bing Liu, Wenjun Li, Bin Yang,* Zeming Qi, Jianwei Zhao, Shikuan Sun, Huixin Lin, Yuanyun Hu, Di Zhou, Dawei Wang*, Ian M. Reaney*, Low permittivity cordierite-based microwave dielectric ceramics for 5G/6G telecommunications,Journal of the European Ceramic Society, 2022, 42, 2820–2826.
[31] Hongliang Tian, Zhijiao Chen, Le Chang, Ruolin Wang, Shaofei Wang, Haiwen Liu*, Chao Du, Di Zhou and Zhewang Ma，Differentially Fed Duplex Filtering Dielectric Resonator Antenna with High Isolation and CM Suppression, IEEE Transactions on Circuits and Systems II: Express Briefs, 2022, 69[3], 979-983.

2021

[217] Guo, Huanhuan; Fu, Maosen; Zhou, Di*; Du, Chao; Wang, Pengjian; Pang, Li-Xia; Liu, Wenfeng; Sombra, Antonio Sergio Bezerra ; Su, Jinzhan, Design of High Efficiency and Gain Antenna Using Novel Low Loss, Temperature Stable Li₂Ti_1-x(Cu_1/3Nb_2/3)_xO₃ Microwave Dielectric Ceramics, ACS Applied Materials & Interfaces, 2021, 13, 1, 912–923.

[216] Shu-Zhao Hao, Di Zhou,* Chao Du, Li-Xia Pang, Charanjeet Singh, Sergei Trukhanovd, and Alex Trukhanov, Antonio Sergio Bezerra Sombra, Jobin Varghese, Qiang Li, Xiu-Qun Zhang, Temperature stable x(Na_0.5Bi_0.5)MoO₄-(1-x)MoO₃ composite ceramics with ultra-low sintering temperatures and low dielectric loss for dielectric resonator antenna applications, ACS Appl. Electron. Mater, 2021, 3, 5, 2286–2296.

[215] Chao Du, Di Zhou,* Huan-Huan Guo, Yong-Qiang Pang, Hong-Yu Shi, Wen-Feng Liu, Charanjeet Singh, Sergei Trukhanov, Alex Trukhanov, and Zhuo Xu, Active Control Scattering Manipulation for Realization of Switchable EIT-like Response Metamaterial, Optics Communications, 2021, 483, 126664.

[214] Chao Du, Mao-Sen Fu, Di Zhou,* Huan-Huan Guo, He-Tuo Chen, Jian Zhang Jun-Ping Wang, Shao-Fei Wang, Hai-Wen Liu, Wen-Feng Liu, Long Li and Zhuo Xu, DielectricResonator Antenna with Y₃Al₅O₁₂ Transparent Dielectric Ceramics for 5G Millimeter-Wave Applications, Journal of the American Ceramic Society, 2021, 104[9], 4659-4668.

[213] Du, Chao; Zhou, Di*; Hao, Shu-Zhao; Chen, Hetuo*; Zhang, Jian; Sun, Shi-Kuan; Zhou, Tao; Dang, Ming-Zhao*; Wang, Shao-Fei; Liu, Hai-wen; Li, Long; Xu, Zhuo, High Quality Factor AlON Transparent Ceramics for 5 GHz Wi-Fi Aesthetic Decoration Antennas, ACS Applied Materials & Interfaces, 2021, 13, 46866−46874.

[212] Fang-Fang Wu, Di Zhou,* Chao Du, Shi-Kuan Sun, Li-Xia Pang, Biao-Bing Jin, Ze-Ming Qi, Jobin Varghese, Qiang Li, and Xiu-Qun Zhang, Temperature stable Sm(Nb_1-xVx)O₄(0.0≤x≤0.9) microwave dielectric ceramics with ultra-low dielectric loss for dielectric resonator antenna applications, Journal of Materials Chemistry C, 2021, 9, 9962–9971.

[211] Da Li, Di Zhou,* Wenyuan Liu, Peng-Jian Wang, Yan Guo,Xiao-Gang Yao, Hui-Xing Lin, Enhanced Energy Storage Properties Achieved in Na_0.5Bi_0.5TiO₃-Based Ceramics via Composition Design and Domain Engineering, Chemical Engineering Journal, 2021, 419, 129601.

[210] Wen-Bo Li, Di Zhou,* Wen-Feng Liu, Jin-Zhan Su, Fayaz Hussain, Da-Wei Wang, Ge Wang, Zhi-Lun Lu, and Qiu-Ping Wang, High-Temperature BaTiO₃-based ternary dielectric multilayers for Energy Storage Applications with extreme high efficiency, Chemical Engineering Journal, 2021, 414, 128760.

[209] Tiezhu Guo, Di Zhou,* Wenfeng Liu and Jinzhan Su, Recent advances in all-in-one flexible supercapacitors, Science China Materials, 2021, 64(1): 27–45.

[208] Tiezhu Guo, MaoSen Fu, Di Zhou,* Lixia Pang, Jinzhan Su, Huixing Lin, Xiaogang Yao, and Antonio Sergio Bezerra Sombra, Flexible Ti3C2Tx/Graphene Films with Large-sized Flakes for Supercapacitors, Small Structures, 2021, 2, 2100015.

[207] Jing Li, Di Zhou,* Chao Du, Peng-Jian Wang, Wen-Feng Liu, Jin-Zhan Su, Li-Xia Pang, Mao-Sheng Cao,* and Ling-Bing Kong,* Recent progress in two-dimensional materials for microwave absorption applications, Chemical Engineering Journal, 2021,425, 131558.

[206] Li-Min Wang, Qing-Xiang Liu, ZhouDi*, Dielectric and energy storage properties of the (1-x)BaTiO₃-xBi(Li_1/3Hf_2/3)O₃ (0.08≤x≤0.14) ceramics, Materials Letters, 2021, 283, 128823.

[205] Dawei Wang, Linhao Li, Juan Jiang, Zhilun Lu, Ge Wang, Kaixin Song, Di Zhou, Ian M. Reaney, Cold sintering of microwave dielectric ceramics and devices, Journal of Materials Research, 2021, 36[2] ‏ 333-349.

[204] Wang, Ge; Lu, Zhilun; Li, Yong; Li, Linhao; Ji, Hongfen; Feteira, Antonio; Zhou, Di; Wang, Dawei; Zhang, Shujun; Reaney, Ian, High Energy Density Electroceramic Capacitors: Current Status and Future Perspectives, Chemical Reviews, 2021, 121, 6124−6172.

[203] R.G.M. Oliveira, J.E.V.de Morais1, D.C. Souza, M.A.S. Silva1, D.X. Gouveia, S. Trukhanov, A. Trukhanov, L. Panina, C. Singh, D. Zhou, A.S.B. Sombra*, High-bandwidth microwave dielectric resonator antennas from BiVO₄/ZnO composites, Journal of the Australian Ceramic Society, 2021, 57:369–377.

[202] A.V. Trukhanov*, D.A. Vinnik, E.A. Trofimov, V.E. Zhivulin, O.V. Zaitseva, S.V. Taskaev, Di Zhou, K.A. Astapovich, S.V. Trukhanov, Yujie Yang, Correlation of the Fe content and entropy state in multiple substituted hexagonal ferrites with magnetoplumbite structure, Ceramics International, 2021, 47, 17684-17692.

[201] Denis A. Vinnik, Andrey Yu. Starikov, Vladimir E. Zhivulin, Kseniya A. Astapovich, Vitaliy A. Turchenko, Tat'yana I. Zubar, Sergei V. Trukhanov*, Jaroslav Kohout, Tomas Kmječ, Olena Yakovenko, Lyudmila Matzui, Antonio Sergio B. Sombra, Di Zhou, Rajshree B. Jotania, Charanjeet Singh, Yujie Yang, and Alex V. Trukhanov, Changes in the Structure, Magnetization, and Resistivity of BaFe_12−xTi_xO₁₉, ACS Appl. Electron. Mater, 2021, 3, 1583−1593.

[200] D.A. Vinnik, A.Yu. Starikov, V.E. Zhivulin, K.A. Astapovich, V.A. Turchenko, T. I. Zubar, S.V. Trukhanov*, J. Kohout, T. Kmječ, O. Yakovenko, L. Matzui, A.S. B. Sombra, D. Zhou, R.B. Jotania, C. Singh, A.V. Trukhanov, Structure and magnetodielectric properties of titanium substituted barium hexaferrites, Ceramics International, 47 (2021) 17293-17306

[199] D. A. Vinnik, V. E. Zhivulin, D. P. Sherstyuk, A. Yu. Starikov, P. A. Zezyulina, S. A. Gudkova, D. A. Zherebtsov, K. N. Rozanov, S. V. Trukhanov*, K. A. Astapovich, A. S. B. Sombra, D. Zhou, R. B. Jotania, C. Singh and A. V. Trukhanov, Ni substitution effect on the structure, magnetization, resistivity and permeability of zinc ferrites, J. Mater. Chem. C, 2021, 9, 5425.

[198] D.A. Vinnik, V.E. Zhivulin, D.P. Sherstyuk, A.Y. Starikov, P.A. Zezyulina, S.A. Gudkova, D.A. Zherebtsov, K.N. Rozanov, S.V. Trukhanov, K.A. Astapovich, V.A. Turchenko, A.S.B. Sombra, D. Zhou, R.B. Jotania, C. Singh, A.V. Trukhanov, Electromagnetic properties of zincenickel ferrites in the frequency range of 0.05-10 GHz, Materials Today Chemistry, 20 (2021) 100460.

[197] D.A. Vinnik*, V.E . Zhivulin, D.A. Uchaev, S.A. Gudkova, D.E. Zhivulin, A. Yu Starikov, S.V. Trukhanov, V.A. Turchenko, T.I. Zubar, T.P. Gavrilova, R.M. Eremina, E. Fadeev, E. Lähderanta, A.S.B. Sombra, Di Zhou, R.B. Jotania, Charanjeet Singh, A.V. Trukhanov, Effect of titanium substitution and temperature variation on structure and magnetic state of barium hexaferrites, Journal of Alloys and Compounds, 2021, 859, 158365.

[196] V.A.Turchenko, S.V. Trukhanov*, V.G. Kostishin, F. Damay, F. Porcher, D. S. Klygach, M.G.Vakhitov, D. Lyakhov, D. Michels, B. Bozzo, I. Fina, M.A. Almessiere, Y. Slimani, A. Baykal, D. Zhou & A.V. Trukhanov, Features of structure, magnetic state and electrodynamic performance of SrFe_12-xIn_xO₁₉, Scientific Reports, 2021, 11:18342.

[195] S.V. Trukhanov*, T.I. Zubar, V.A. Turchenko, An.V. Trukhanov, T. Kmječ, J. Kohout, L. Matzui, O. Yakovenko, D.A. Vinnik, A.Yu. Starikov, V.E. Zhivulin, A.S.B. Sombra, D. Zhou, R.B. Jotania, C. Singh, A.V. Trukhanov, Exploration of crystal structure, magnetic and dielectric properties of titanium-barium hexaferrites, Materials Science and Engineering: B, 2021, 272, 115345.

[194] Hai-Wen Liu,* Hong-Liang Tian, Chao Du, Tao-Tao Huang, Zhen-Yu Zhao, and Di Zhou, Dual-Band Filtering Dielectric Antenna Using High-Quality-Factor Y₃Al₅O₁₂ Transparent Dielectric Ceramic, Advanced Engineering Materials, 2021, 23, 2100115.

[193] Di Zhou*, Huan-Huan Guo, Mao-Sen Fu, Xiao-Gang Yao, Hui-Xing Lin, Wen-Feng Liu, Li-Xia Pang, Charanjeet Singh, Sergei Trukhanovh, Alex Trukhanovh, & Ian M. Reaney*, Anomalous Dielectric Behaviour at the Monoclinic to Tetragonal Phase Transition in La(Nb_0.9V_0.1)O₄, Inorganic Chemistry Frontiers, 2021, 8, 156-163.

[192] Bing Liu, Ke Sha, Ying Qiang Jia, Yu Hui Huang, Cheng Chao Hu, Lei Li, Da Wei Wang, Di Zhou, Kai Xin Song, High quality factor cold sintered LiF ceramics for microstrip patch antenna applications, Journal of the European Ceramic Society, 2021, 41[9], 4835-4840.

[191] Bing Liu, Lei Li, Kai Xin Song, Min Min Mao, Zhilun Lu, Ge Wang, Linhao Li, Dawei Wang, Di Zhou, Antonio Feteira, Ian M. Reaney, Enhancement of densification and microwave dielectric properties in LiF ceramics via a cold sintering and post-annealing process, Journal of the European Ceramic Society, 2021, 41, 1726–1729.

[190] Mingtao Ma, Kaixin Song*, Yuping Ji, Fayaz Hussain, Amir Khesro, Minmin Mao, Lingyun Xue, Ping Xu, Bing Liu, Zhilun Lu, Di Zhou, Dawei Wang*, Shikuan Sun, 5G microstrip patch antenna and microwave dielectric properties of cold sintered LiWVO₆–K₂MoO₄ composite ceramics, Ceramics International, 2021, 47, 19241–19246.

[189] Y Ji, K Song, S Zhang, Z Lu, G Wang, L Li, Di Zhou, D Wang, IM Reaney, Cold sintered, temperature-stable CaSnSiO₅-K₂MoO₄ composite microwave ceramics and its prototype microstrip patch antenna, Journal of the European Ceramic Society, 2021, 41, 424-429.

[188] Jasbir Singh, Charanjeet Singh*, Dalveer Kaur, Sukhleen Bindra Narang, Rajshree B. Jotania, Ebtesam Ateia, Amrin Kagdi, Rajat Joshi, A.S.B. Sombra, Di Zhou, Sergei Trukhanov, Larrisa Panina, Development of doped BaeSr hexagonal ferrites for microwave absorber applications: Structural characterization, tunable thickness, absorption peaks and electromagnetic parameters, Journal of Alloys and Compounds, 2021, 855, 157242.

[187] Jasbir Singh, Charanjeet Singh*, Dalveer Kaur, Sukhleen Bindra Narang, Rajshree B. Jotania, Amrin Kagdi, Rajat Joshi, Antonio Sergio Bezerra Sombra, Di Zhou, Sergei Trukhanov, Larrisa Panina, and Alex Trukhanov, Optimization of Performance Parameters of Doped Ferrite-Based Microwave Absorbers: Their Structural, Tunable Reflection Loss, Bandwidth, and Input Impedance Characteristics, IEEE Transactions on Magnetics, 2021, 57[7], 2800619.

[186] Charanjeet Singh*, Mari Vesna Nikolic, Sukhleen Bindra Narang, Antonio Sergio Bezerra Sombra, Di Zhou, Sergei Trukhanov, Larrisa Panina, Jasbir Singh, Alex Trukhanov, Controllable Morphology, Dielectric, Magnetic and Reflection loss Characteristics of Ferrite/Wax Composites for Low-loss Applications, Journal of Alloys and Compounds, 2021, 161611.

2020

[185] Wang D, Chen J, Wang G, Lu Z, Sun S, Li J, Jiang J, Zhou Di, Song K & Reaney IM, Cold sintered LiMgPO₄ based composites for low temperature co-fired ceramic (LTCC)         applications, Journal of the American Ceramic Society, 2020, 103 (11), 6237-6244.

[184] Charanjeet Singh, Maria Vesna Nikolic, Sukhleen Bindra Narang, A.S.B. Sombra, Di Zhou, Sergei Trukhanov, Larrisa Panina, Jasbir Singh, Alex Trukhanov, Complex permittivity and complex permeability characteristics of Co–Ti doped barium strontium hexaferrite/paraffin wax composites for application in microwave devices, Applied Physics A, 2020, 126:850.

[183] Peng-Jian Wang, Di Zhou,* Huan-Huan Guo, Wen-Feng Liu, Jin-Zhan Su, Sergei Trukhanov, Alex Trukhanov, Significantly Enhanced Electrostatic Energy Storage Performance of P(VDF-HFP)/BaTiO₃-Bi(Li_0.5Nb_0.5)O₃ Nanocomposites, Nano Energy, 2020, 78, 105247.

[182] Peng-Jian Wang, Di Zhou,* Huan-Huan Guo, Wen-Feng Liu, Jin-Zhan Su, Sergei Trukhanov, Alex Trukhanov, Ultrahigh enhancement rate of the energy density of flexible polymer nanocomposites using core-shell BaTiO3@MgO structures as the filler, Journal of Materials Chemistry A, 2020, 8, 11124–11132. 

     (This article is part of the themed collection: Journal of Materials Chemistry A HOT Papers)

[181] Jing Li, Di Zhou,* Pengjian Wang, Wenfeng Liu, Jinzhan Su, Raspberry-like LiFe₅O₈nanoparticles embed on MoS₂ microflower with high-performance microwave absorption, Journal of Materials Chemistry A, 2020, 8, 20337 - 20345.

[180] Huan-Huan Guo, Di Zhou,* Chao Du, Peng-Jian Wang, Wen-Feng Liu, Li-Xia Pang, Qiu-Ping Wang, Jin-Zhan Su, Charanjeet Singh and Sergei Trukhanov, Temperature stable Li₂Ti_0.75(Mg_1/3Nb_2/3)_0.25O₃-based microwave dielectric ceramics with low sintering temperature and ultra-low dielectric loss for dielectric resonator antenna applications, Journal of Materials Chemistry C, 2020, 8, 4690-4700. 

     (Front cover paper，入选Lunar New Year collection 2021)

[179] Chao Du, Huan-Huan Guo, Di Zhou,* He-Tuo Chen, Jian Zhang, Wen-Feng Liu, Jin-Zhan Su and Hai-Wen Liu, Dielectric Resonator Antennas based on High Quality Factor MgAl₂O₄ Transparent Dielectric Ceramics,Journal of Materials Chemistry C, 2020, 8, 14880-14885.

[178] Chao Du, Di Zhou,* Huan-Huan Guo, Yong-Qiang Pang, Hong-Yu Shi, Wen-Feng Liu, Jin-Zhan Su, Charanjeet Singh, Sergei Trukhanov, Alex Trukhanov, Larissa Panina and Zhuo Xu, Ultra-broadband terahertx metamaterials coherent absorber using multilayer electric ring resonator structures based on anti-reflection coating, Nanoscale, 2020,12, 9769-9775.

[177] Huan-Huan Guo, Di Zhou,* Wen-Feng Liu, Li-Xia Pang, Da-Wei Wang, Jin-Zhan Su, and Ze-Ming Qi, Microwave Dielectric Properties of Temperature-Stable Zircon-Type (Bi, Ce)VO₄ Solid-Solution Ceramics, Journal of the American Ceramic Society, 2020, 103[1], 423-431.

[176] Jing Li, Di Zhou,* Enhanced Microwave Absorption of Reduced Graphene Oxide/Ni_0.4Zn_0.4Co_0.2Fe₂O₄ Composite at Ultrathin Thickness, Journal of Electronic Materials, 2020, 49[3], 1721-1727.

[175] Shu-Zhao Hao, Di Zhou,* Fayaz Hussain, Wen-Feng Liu, Jin-Zhan Su, Da-Wei Wang, Qiu-Ping Wang, Ze-Ming Qi, Charanjeet Singh and Sergei Trukhanov, Spectra analysis and microwave dielectric properties of a novel x(NaBi)_0.5MoO₄-(1-x)Bi₂(MoO₄)₃ ceramics with low sintering temperature, Journal of the European Ceramic Society, 2020, 40[10], 3569-3576.

[174] Shu-Zhao Hao, Di Zhou,* Fayaz Hussain, Jin-Zhan Su, Wen-Feng Liu, Da-Wei Wang, Qiu-Ping Wang and Ze-Ming Qi, Novel Scheelite-Type [Ca_0.55(Nd_1-xBi_x)_0.3]MoO₄ (0.2<x<0.95) Microwave Dielectric Ceramics with Low Sintering Temperature, Journal of the American Ceramic Society, 2020, 103, 7259–7266.

[173] Lei Zhang, Wen-Bo Li, Li-Xia Pang,* Di Zhou,* Extreme high energy storage efficiency in perovskite structured (1-x)(Ba_0.8Sr_0.2)TiO₃-xBi(Zn_2/3Nb_1/3)O₃ (0.04≤x≤0.16) ceramics, Journal of the European Ceramic Society, 2020, 40[8], 3343-3347.

[172] Lu, Yumeng; Su, Jinzhan*; Shi, Jinwen; ZhouDi, Surface recombination passivation of BiVO₄ photoanode by synergistic effect of cobalt/nickel sulfide cocatalyst, ACS Applied Energy Materials, 2020, 3[9] 9089–9097.

[171] Qianbi Lin, Kaixin Song, Bing Liu, Hadi Barzegar Bafrooei, Di Zhou, Weitao Su, Feng Shi, Dawei Wang, Huixin Lin, Ian M Reaney, Vibrational spectroscopy and microwave dielectric properties of AY₂Si₃O₁₀ (A= Sr, Ba) ceramics for 5G applications, Ceramic International, 2020, 46 (1), 1171-1177.

[170] Dawei Wang, Shiyu Zhang, Ge Wang, Yiannis Vardaxoglou, Will Whittow, Darren Cadman, Di Zhou, Kaixin Song, Ian M Reaney, Cold sintered CaTiO₃-K₂MoO₄ microwave dielectric ceramics for integrated microstrip patch antennas, Applied Materials Today, 2020, 18, 100519

[169] Nurul Aida Mohamed, Javad Safaei, Aznan Fazli Ismail, Muhammad Najib Khalid, Muhammad Fareez Amir Mohd Jailani, Mohamad Firdaus Mohamad Noh, Nurul Affiqah Arzaee, Di Zhou, Jagdeep S. Sagu and Mohd Asri Mat Teridi, Boosting photocatalytic activities of BiVO₄ by creation of g-C₃N₄/ZnO@BiVO₄ Heterojunction, Materials Research Bulletin, 2020, 125, 110779.

[168] Moustafa A. Darwish, Alex V. Trukhanov, Oleg S. Senatov, Alexander T. Morchenko, Samia A. Saafan, Ksenia A. Astapovich, Sergei V. Trukhanov, Ekaterina L. Trukhanova, Andrey A. Pilyushkin, Antonio Sergio B. Sombra, Di Zhou, Rajshree B. Jotania, and Charanjeet Singh, Investigation of AC-Measurements of Epoxy/Ferrite Composites, Nanomaterials, 2020, 10, 492.

[167] Tatiana Zubar, Valery Fedosyuk, Daria Tishkevich, Oleg Kanafyev, Ksenia Astapovich, Artem Kozlovskiy, Maxim Zdorovets, Denis Vinnik, Svetlana Gudkova, Egor Kaniukov, Sergio Sombra, Di Zhou, Rajshree B. Jotania, Charanjeet Singh, Sergei Trukhanov*, Alex Trukhanov,The effect of heat treatment on the microstructure and mechanical properties of 2D nanostructured Au/NiFe system, Nanomaterials, 2020,10, 1077.

[166] Dawei Wang, Beatia Siame, Shiyu Zhang, Ge Wang, Xingshen Ju, Jinglei Li, Zhilun Lu, Yiannis Vardaxoglou, Will Whittow, Darren Cadman, Shikuan Sun, Di Zhou, Kaixin Song, Ian M Reaney, Direct Integration of Cold Sintered, Temperature-Stable Bi₂Mo₂O₉-K₂MoO₄ Ceramics on Printed Circuit Boards for Satellite Navigation Antennas, Journal of the European Ceramic Society, 2020, 40, 4029–4034.

[165] Fayaz HUSSAIN, Amir Khesro, Zhilun Lu, Nouf Alotaibi, AHMAD AZMIN MOHAMAD, Ge Wang, Di Zhou, Dawei Wang, Acceptor and Donor, Dopants in Potassium Sodium Niobate Based Ceramics, Frontiers in Materials, 2020, 7, 160.

[164] A.V. Trukhanov, K.A. Astapovich, V.A. Turchenko, M.A. Almessiere, Y. Slimani, A. Bayka, A.S.B. Sombra, Di Zhou, R.B. Jotania, C. Singh, T.I. Zubar, D.I. Tishkevich, S.V. Trukhanov, Influence of the dysprosium ions on structure, magnetic characteristics and origin of the reflection losses in the Ni-Co spinels, Journal of Alloys Compound, 2020,841, 155667

[163] Ronaldo Glauber Maia de Oliveira, D; D. C. Souza; J. E. V. de morais; G. S. Batista; M. A. S. Silva; D. X. Gouveia; S. Trukhano; A. Trukhanov; L. Panina; C. Singh; D. Zhou; A. S. B. Sombra, "High Thermal Stability of RF Dielectric Properties of BiVO₄ Matrix with added ZnO", Journal of Materials Science: Materials in Electronics, 2020, 31:13078–13087.

 

2019 

[162] Dawei Wang*, Shiyu Zhang, Di Zhou, Kaixin Song, Antonio Feteira, Yiannis Vardaxoglou, Will Whittow, Darren Cadman, Ian M Reaney,* Temperature stable cold sintered (Bi_0.95Li_0.05)(V_0.9Mo_0.1)O₄-Na₂Mo₂O₇ microwave dielectric composites, Materials, 2019, 12 (9), 1370.

[161] Ge Wang, Jinglei Li, Xun Zhang, Zhongming Fan, Fan Yang, Antonio Feteira, Di Zhou, Derek C. Sinclair, Tao Ma, Xiaoli Tan, Dawei Wang* and Ian M. Reaney, Ultrahigh energy storage density lead-free multilayers by controlled electrical homogeneity, 2019, Energy Environ. Sci. 2019, 12, 582-588.

[160] Di Zhou*, Li-Xia Pang, Da-Wei Wang, Ian M. Reaney*, Novel water-assisting low firing MoO₃ microwave dielectric ceramics,  Journal of the European Ceramic Society, 39 (2019) 2374–2378.

[159] Huan-Huan Guo, Di Zhou*, Li-Xia Pang and Ze-Ming Qi, Microwave Dielectric Properties of Low Firing Temperature Stable Scheelite Structured (Ca,Bi)(Mo,V)O₄ Solid Solution Ceramics for LTCC applications, Journal of the European Ceramic Society, 39 (2019) 2365–2373. 

[158] Li-Xia Pang, Di Zhou*, Zhen-Xing Yue, Temperature independent low firing [Ca_0.25(Nd_1-xBi_x)_0.5]MoO₄ (0.2 ≤ x ≤ 0.8) microwave dielectric ceramics, Journal of Alloys and Compounds, 2019, 781, 385-388.

[157] Li-Xia Pang, Di Zhou*, Modification of NdNbO₄ microwave dielectric ceramic by Bi substitutions, Journal of the American Ceramic Society, 2019;102:2278–2282.

[156] Shu-Zhao Hao, Di Zhou* and Li-Xia Pang, The Spectra analysis and Microwave Dielectric Properties of [Ca_0.55(Sm_1-xBi_x)_0.3]MoO₄ Ceramics, Journal of the American Ceramic Society, 2019, 102 (6), 3103-3109.

[155] Jing Li, Di Zhou*, Influence of Ag doping on the dielectric and magnetic properties of LiFe₅O₈ ceramics, Journal of Alloys and Compounds, 2019, 785, 13-18.

[154] J Li, Di Zhou*, WF Liu, JZ Su, MS Fu, Novel and facile reduced graphene oxide anchored Ni-Co-Zn-Nd-ferrites composites for microwave absorption, Scripta Materialia 2019, 171, 42-46.

[153] Li, Wenbo; Di Zhou*; Xu, Ran; Wang, Da-Wei; Su, Jinzhan; Pang, Li-Xia; Liu, Wenfeng; Chen, Guo-Hua, “BaTiO₃-Based Multilayers with Outstanding Energy Storage Performance for High Temperature Capacitor Applications", ACS Applied Energy Materials, 2019, 2 (8), 5499-5506.

[152] Zhili Ma, Jinxiong Zhao, and Di Zhou*, Microwave dielectric properties of the (1−x)La(Nb_0.9V_0.1)O₄-xCaMoO₄ (0.05≤x≤0.50) scheelite solid solution ceramics,Journal of Alloys and Compounds, 789 (2019) 345-350.

[151] Dawei Wang*, Di Zhou, Kaixin Song, Antonio Feteira, Clive A. Randall, and Ian M. Reaney,Cold Sintered C0G Multilayer Ceramic Capacitors, Advanced Electronic Materials, 2019, 1900025.

[150] Feng Shi, He-Lei Dong, Di Zhou, Chun-Hai Wang, Qiu-Lin Tan, Ji-Jun Xiong, Qing Wang, Lattice dynamics and phonon characteristics of complex perovskite microwave ceramics, IET Nanodielectrics,2019, Vol. 2 Iss. 1, pp. 11-26.

 

2018

[149] Dawei Wang, Zhongming Fan, Wenbo Li, Di Zhou, Antonio Feteira, Ge Wang, Shunsuke Murakami, Shikuan Sun, Quanliang Zhao, Xiaoli Tan, Ian M Reaney, High energy storage density and large strain in Bi(Zn_2/3Nb_1/3)O₃-Doped BiFeO₃-BaTiO₃ ceramics, ACS Appl. Energy Mater., 2018, 1 (8) 4403-4412. 

[148] Dawei Wang, Ge Wang, Shunsuke Murakami, Zhongming Fan, Antonio Feteira, Di Zhou, Shikuan Sun, Quanliang Zhao, Ian M Reaney,BiFeO₃-BaTiO₃: a new generation of lead-free electroceramics，Journal of Advanced Dielectrics, 2018. 8(5), 1830004.

[147] Di Zhou*, LX Pang, DW Wang, Ian M. Reaney*, BiVO₄ based high k microwave dielectric materials: a review,  (Review Article)J. Mater. Chem. C, 2018, 6, 9290-9313. 

[146] Di Zhou*, LX Pang, DW Wang, ZM Qi, Ian M. Reaney*, High Quality Factor, Ultralow Sintering Temperature Li₆B₄O₉ Microwave Dielectric Ceramics with Ultralow Density for Antenna Substrates, ACS Sustainable Chem. Eng., 2018, 6 (8), pp 11138–11143. 

[145] Di Zhou*, LX Pang, DW Wang, HH Guo, F Yang, ZM Qi, C Li, BB Jin, Ian M. Reaney*, Crystal structure, impedance and broadband dielectric spectra of ordered scheelite-structured Bi(Sc_1/3Mo_2/3)O₄ ceramic, Journal of the European Ceramic Society, 2018, 38[4], 1556-1561. 

[144] Wen-Bo Li, Di Zhou*, Ran Xu, Li-Xia Pang, Ian M Reaney, BaTiO₃-Bi(Li_0.5Ta_0.5)O₃, Lead-Free Ceramics and Multilayers with High Energy Storage Density and Efficiency, ACS Applied Energy Materials, 2018, 1 (9), 5016-5023.

[143] LX Pang, Di Zhou*, WG Liu, ZM Qi, ZX Yue, Crystal structure and microwave dielectric behaviors of scheelite structured (1-x) BiVO₄-xLa_2/3MoO₄ (0.0≤ x≤ 1.0) ceramics with ultra-low sintering temperature, Journal of the European Ceramic Society, 2018, 38[4], 1535-1540. 

[142] Li-Xia Pang, Di Zhou*, Da-Wei Wang, Jin-Xiong Zhao, Wei-Guo Liu, Zhen-Xing Yue, Ian M Reaney, Temperature stable K_0.5(Nd_1-xBi_x)_0.5MoO₄ microwave dielectrics ceramics with ultra-low sintering temperature, Journal of the American Ceramic Society, 2018, 101[5], 1806–1810. 

[141] Huan-Huan Guo, Di Zhou*, Li-Xia Pang, Jin-Zhan Su, Influence of (Mg_1/3Nb_2/3) complex substitutions on crystal structures and microwave dielectric properties of Li₂TiO₃ ceramics with extreme low loss, Journal of Materiomics, 2018, 4(4), 368-382.

[140] Dawei Wang, Di Zhou, Shiyu Zhang, Yiannis Vardaxoglou, William G Whittow, Darren Cadman, Ian M Reaney, Cold-Sintered Temperature Stable Na_0.5Bi_0.5MoO₄-Li₂MoO₄ Microwave Composite Ceramics, ACS Sustainable Chem. Eng., 2018, 6 (2), 2438–2444. 

[139] Dawei Wang, Zhongming Fan, Di Zhou, Amir Khesro, Shunsuke Murakami, Antonio Feteira, Quanliang Zhao, Xiaoli Tan, Ian M Reaney, Bismuth ferrite-based lead free ceramics and multilayers with high recoverable energy density, J. Mater. Chem. A, 2018, 6, 4133-4144. 

 

2017

[138] Xianghu Tan, Huanfu Zhou, Yuxin Tang, Di Zhou, Pushkar Kanhere, Qiuling Tay and Xiuli Chen, Li_4x/3Co_2−2xTi_1+2x/3O₄ spinel solid solutions: order and disorder phase transition, cations distribution and adjustable microwave dielectric properties, RSC Adv., 2017, 7, 51670.

[137]Tan, Xianghu; Zhou, Huanfu*; Tang, Yuxin;ZhouDi; Kanhere, Pushkar; Tay, Qiuling; Chen, Xiuli, Li_4x/3Co_2-2xTi_1+2x/3O₄ spinel solid solutions: order and disorder phase transition, cations distribution and adjustable microwave dielectric properties, RSC Advances, 2017, 7 [81], 51670-51677.  

[136] Di Zhou*, Jing Li, Li-Xia Pang, Da-Wei Wang, Ian M Reaney, Novel water insoluble and sustainable (Na_xAg_2-x)MoO₄ (0 ≤ x ≤ 2) microwave dielectric ceramics with spinel structure sintered at 410 degrees, Journal of Materials Chemistry C, 2017, 5, 6086 - 6091. 

[135] Di Zhou*, Li-Xia Pang, Da-Wei Wang, Chun Li, Biao-Bing Jin & Ian M. Reaney*, High permittivity, low loss microwave dielectrics suitable for 5G resonator and low temperature co-fired ceramic architecture, Journal of Materials Chemistry C, 2017, 5 (38), 10094-10098.

[134] Li-Xia Pang, Di Zhou*, Ze-Ming Qi, Wei-Guo Liu, Zhen-Xing Yue and Ian M. Reaney, Structure–property relationships of low sintering temperature scheelite-structured (1-x)BiVO₄–xLaNbO₄ microwave dielectric ceramics, Journal of Materials Chemistry C, 2017, 5, 2695-2701.

[133] Wen-Bo Li, Di Zhou*, Li-Xia Pang, Ran Xu and Huan-Huan Guo, Novel Barium titanate based capacitors with high energy density and fast discharge performance, Journal of Materials Chemistry A, 2017, 5 (37), 19607-19612.

[132] Li-Xia Pang, Di Zhou*, Wen-Bo Li and Zhen-Xing Yue, High quality microwave dielectric ceramic sintered at extreme-low temperature below 200 degrees and co-firing with base metal, Journal of the European Ceramic Society, 2017, 37[9], 3073–3077.

[131] Dan Guo, Di Zhou*, Wen-Bo Li, Li-Xia Pang, Yan-Zhu Dai, Ze-Ming Qi, Phase Evolution, Crystal Structure and Microwave Dielectric Properties of Water Insoluble (1-x)LaNbO₄-xLaVO₄ (0 < x < 0.9) Ceramics, Inorganic Chemistry, 2017,56 (15), 9321-9329.

[130] Li-Xia Pang, Di Zhou*, Ze-Ming Qi, Zhen-Xing Yue, Influence of W substitution on crystal structure, phase evolution and microwave dielectric properties of (Na_0.5Bi_0.5)MoO₄ ceramics with low sintering temperature, Scientific Reports, 2017, 7, 3201.

[129] Wen-Bo Li, Di Zhou*, Li-Xia Pang, Enhanced energy storage density by inducing defect dipoles in lead free relaxor ferroelectric BaTiO₃ based ceramics, Applied Physics Letters, 2017, 110, 132902. (Highly Cited Editor's Picks) 

[128] Wen-Bo Li, Di Zhou*, Dan Guo, Li-Xia Pang, Guo-Hua Chen, Ze-Ming Qi, Qiu-Ping Wang, and Han-Chen Liu, Structure, Raman spectra, far-infrared spectra and microwave dielectric properties of temperature independent CeVO₄-TiO₂ composite ceramics, Journal of Alloys and Compounds, 2017, 694, 40-45.

[127] Wen-Bo Li, Di Zhou*, Li-Xia Pang, Structure and energy storage properties of Mn-doped (Ba,Sr)TiO₃–MgO composite ceramics, J Mater Sci: Mater Electron, 2017, 28, 8749–8754.

[126] Wen-Bo Li, Di Zhou*, Shu-Zhao Hao, Guo-Hua Chen, Ze-Ming Qi, Qiu-Ping Wang, Han-Chen Liu, and Xi Yao, Ultra-low loss microwave dielectric ceramics in (Mg_1/3Nb_2/3)O₂-ZrO₂-TiO₂ ternary system, Journal of the American Ceramic Society, 2017;100:3982–3989.

[125] Shu-Zhao Hao, Di Zhou*, Wen-Bo Li, Microwave Dielectric Properties of BiCu₂PO₆ Ceramics with Low Sintering Temperature, Journal of Electronic Materials, 2017, 46 (11), 6241-6245.

[124] VV Atuchin, AS Aleksandrovsky, MS Molokeev, AS Krylov, AS Oreshonkov, Di Zhou, Structural and spectroscopic properties of self-activated monoclinic molybdate BaSm₂(MoO₄)₄, Journal of Alloys and Compounds, 2017, 729, 843-849.

 

2016

[123] Tao, Fengqiong; Genevois, Cecile; Lu, Fengqi; Kuang, Xiaojun*; Porcher, Florence; Li, Liangju; Yang, Tao; Li, Wenbo; Zhou Di; Allix, Mathieu, The First 14-Layer Twinned          Hexagonal Perovskite Ba₁₄Mn_1.75Ta_10.5O₄₂: Atomic-Scale Imaging of Cation Ordering, Chem. Mater., 2016, 28, 4686−4696.

[122] Di Zhou*, Dan Guo, Wen-Bo Li, Li-Xia Pang, Xi Yao, Da-Wei Wang, Ian M Reaney, Novel temperature stable high-ε_r microwave dielectrics in the Bi₂O₃–TiO₂–V₂O₅ system, Journal of Materials Chemistry C, 2016, 4, 5357-5362.   

[121] Di Zhou*, Xiao-Qin Fan, Xiao-Wei Jin, Duan-Wei He, and Guo-Hua Chen, Structures, Phase Transformations, and Dielectric Properties of BiTaO₄ Ceramics, Inorganic Chemistry, 2016, 55, 11979−11986.  

[120] Di Zhou*, Jing Li, Li-Xia Pang, Guo-Hua Chen, Ze-Ming Qi, Da-Wei Wang, and Ian M. Reaney, Crystal Structure, Infrared Spectra, and Microwave Dielectric Properties of Temperature-Stable Zircon-Type (Y,Bi)VO₄ Solid-Solution Ceramics, ACS Omega, 2016, 1, 963−970.  

[119] Wen-Bo Li, Di Zhou*, Hai-Hong Xi, Li-Xia Pang, Xi Yao, Structure, Infrared Reflectivity and Microwave Dielectric Properties of (Na_0.5La_0.5)MoO₄–(Na_0.5B_i0.5)MoO₄Ceramics, Journal of the American Ceramic Society, 2016, 99 [6] 2083–2088.  

[118] Yi-Ding Zhang, Di Zhou*, Pseudo Phase Diagram and Microwave Dielectric Properties of Li₂O-MgO-TiO₂ Ternary System, Journal of the American Ceramic Society, 2016, 99 [11] 3645–3650.  

[117] Wen-Bo Li, Di Zhou*, Bin He, Fei Li, Li-Xia Pang, Sheng-Guo Lu, Structure and dielectric properties of Nd(Zn_1/2Ti_1/2)O₃–BaTiO₃ ceramics for energy storage applications, Journal of Alloys and Compounds, 2016, 685, 418–422. 

[116] Li-Xia Pang, Di Zhou*, Wei-Guo Liu, Zhen-Xing Yue, Phase evolution and dielectric properties of fluorite-type Bi₃(Nb_0.9M_0.1)O_7+δ ceramics (M= Ti, Zr, Sn, W, δ=±0.05), Journal of Alloys and Compounds, 2016, 674, 89-92.

[115] Li-Xia Pang, Wei-Guo Liu, Di Zhou*, Zhen-Xing Yue, Phase evolution and microwave dielectric properties of (Bi_1-xLn_x)₂MoO₆ (Ln= Nd and La, x≤ 0.3) ceramics, Ceramics International, 2016, 42[15], 17243-17247. 

[114] Li-Xia Pang, Wei-Guo Liu, Di Zhou*, Zhen-Xing Yue, Novel glass-free low-temperature fired microwave dielectric ceramics: Bi(Ga_1/3Mo_2/3)O₄, Ceramics International, 2016, 42[3], 4574-4577.  

[113] Jinxiong Zhao, Yuyu Tian, Zhen Wang, Shan Cong, Di Zhou, Qingzhu Zhang, Mei Yang, Weikun Zhang, Fengxia Geng, and Zhigang Zhao*, Trace H₂O₂-Assisted High-Capacity Tungsten Oxide Electrochromic Batteries with Ultrafast Charging in Seconds, Angew. Chem. Int. Ed., 2016, 55, 7161 –7165. 

 

2015

[112] Huidong Xie, Fei Li, Haihong Xi & Di Zhou, Microwave Dielectric Properties of Sol-Gel Processed Bi₄Si₃O₁₂ Ceramics and Single Crystal, Transactions of the Indian Ceramic Society, 2015, 74[2], 83-85.

[111] Zhou D*, Li WB, Xi HH, Pang LX, and Pang GS, Phase composition, crystal structure, infrared reflectivity and microwave dielectric properties of temperature stable composite ceramics (scheelite and zircon-type) in BiVO₄-YVO₄ system, Journal of Materials Chemistry C, 2015, 3, 2582–2588.  

[110] Zhou D*, Li WB, Pang LX, Yue ZX, Pang GS, and Yao X. Abnormal dielectric properties and phase transition in Bi_0.783(Mo_0.65V_0.35)O₄ scheelite-related structured ceramic, RSC Advances, 2015, 5, 19255–19258.  

[109] Xi HH, Zhou D*,  Xie HH, and Li WB, Microwave dielectric properties of low firing scheelite-related (Na_0.5La_0.5)MoO₄ ceramic, Materials Letters, 2015, 142, 221-224.  

[108] Xi HH, Zhou D*,  Xie HH, He B and Wang QP, Raman Spectra, Infrared Spectra, and Microwave Dielectric Properties of Low-Temperature Firing [(Li_0.5Ln_0.5)_1−xCa_x]MoO₄ (Ln = Sm and Nd) Solid Solution Ceramics with Scheelite Structure, Journal of the American Ceramic Society, 2015, 98 [2] 587-593.  

[107] Pang LX, Zhou D*,  Guo J, Yue ZX, and Yao X, Microwave Dielectric Properties of (Li_0.5Ln_0.5)MoO₄ (Ln = Nd, Er, Gd, Y, Yb, Sm, and Ce) Ceramics, J. Am. Ceram. Soc., 2015, 98, 130-135.  

[106] Pang LX, Liu WG, and Zhou D*, Temperature stable high K microwave dielectric ceramics of Bi₃NbO₇ doped by V₂O₅,  Ceramics International, 2015, 41, 5182–5185.  

[105] Xi HH, Zhou D*,  Xie HH, and Li WB, Microwave dielectric properties of low firing (Na_0.5Ln_0.5)MoO₄ (Ln=Nd and Ce) ceramics,  Ceramics International, 2015, 41, 6103– 6107.  

[104] Li WB, Xi HH, and Zhou D*, Microwave dielectric properties of BaY₂(MoO₄)₄ ceramic with low sintering temperature,  Journal of Materials Science: Materials in Electronics, 2015, 26, 1608–1611.  

[103] Li, Wen-Bo; Xi, Hai-Hong; Zhou D*, Microwave dielectric properties of LiMVO₄ (M = Mg, Zn) ceramics with low sintering temperatures, Ceramics International, 2015, 41, 9063-9068.  

[102] Li, Wen-Bo; Xi, Hai-Hong; Zhou D*, Microwave Dielectric Properties of Temperature-Stable BaLn₂(MoO₄)₄-TiO₂ (Ln = Ce, Nd, and Sm) Ceramics, Journal of Electronic Materials, 2015, 44[11], 4250-4254.  

[101] Zhang, Yi-Ding; Han, Jun; Liang, Rui;  Zhou D*, Novel temperature stable Li₂TiO₃-based microwave dielectric ceramics with low loss, Materials Letters, 2015, 153, 118-120. 

[100] Zhai Xiao-Liu, Zheng Xu, Xi Hai-Hong, Li Wen-Bo, Han Jun, and Zhou D*, Microwave Dielectric Properties of LiKSm₂(MoO₄)₄ Ceramics with Ultralow Sintering Temperatures, J. Am. Ceram. Soc., 2015, 98 [9] 2716-2719.

[99] Zhou JH, Xu NX, Zhang QL*, Zhou D,  Tang X and Yang H, Low-temperature densification of Mg₂SnO₄ ceramics with LiF-Fe₂O₃-V₂O₅ additive,  Materials Letters, 2015, 139, 169-172.  

[98] He Li, Mi Shao-Bo, Jin Xiaowei, Zhang Hui, Zhou Di, Xiang Feng, Yang Haibo, Wang Hong*, Order-Disorder Phase Transition and Magneto-Dielectric Properties of (1-x)LiFe₅O₈-xLi₂ZnTi₃O₈ Spinel-Structured Solid Solution Ceramics,  J. Am. Ceram. Soc., 2015, 98 [7], 2122-2129.  

[97] Xie HD*, Xi HH, Chen C, Zhou D, Microwave dielectric properties of two low temperature sintering ceramics in the PbO-WO₃ binary system, Ceramics International, 2015, 41 [8], 10287-10292.

[96] Guo Jing, Randall Clive, Zhou Di, Zhang Gaoqun, Zhang Caihong, Jin Biaobing, Wang Hong*, Correlation between vibrational modes and dielectric properties in (Ca_1−3xBi_2xΦ_x)MoO₄ ceramics, J. Eur. Ceram. Soc., 2015, 35 [16], 4459-4464.

2014

[95] Zhou D*, Pang LX, Xie HD, Guo J, He B, Qi ZM, Shao T, Yao X and Randall CA, Crystal structure and microwave dielectric properties of a novel ultra-low temperature fired          (AgBi)_0.5WO₄ ceramic, European Journal of Inorganic Chemistry, 2014, 2, 296–301.  

[94] Zhou D*, Pang LX, Guo J, Qi ZM, Shao T, Wang QP, Xie HD, Yao X and Randall CA, Influence of Ce Substitution for Bi in BiVO₄ and the Impact on the Phase Evolution and        Microwave Dielectric Properties, Inorganic Chemistry, 2014, 53[2], 1048-1055.

[93] Zhou D*, Li WB, Pang LX, Guo J, Qi ZM, Shao T, Yao X, and Randall CA, Phase evolution and microwave dielectric properties of xBi_2/3MoO₄-(1-x)BiVO₄ (0.0≤x≤1.0) low          temperature firing ceramics, Dalton Transactions, 2014, 43, 7290-7297.  

[92] Zhou D*, Xu C, He DW, Fu MS, Guo J, Zhou HF, Pang LX, Yao X. Dielectric Properties and Phase Transitions of BiNbO₄ Ceramic, Scripta Materialia, 2014, 81, 40-43.  

[91] Zhou D*, Li, WB, Guo J, Pang LX, Qi ZM, Shao T, Xie HD, Yue ZX, and Yao X,Structure, Phase Evolution, and Microwave Dielectric Properties of (Ag_0.5Bi_0.5)(Mo_0.5W_0.5)          O₄ Ceramic with Ultra low Sintering Temperature, Inorganic Chemistry, 2014, 53, 5712-5716.  

[90] Zhou D*, He B, Guo J, Pang LX, Qi ZM, Shao T, Wang QP, Yue ZX, and Yao X, Phase Evolution and Microwave Dielectric Properties of (Bi_1–xFe_x)VO₄ (x ≤ 0.40) Ceramics,          J. Am. Ceram. Soc., 2014, 97, 2915-2920.

[89] Zhou D*, Li, WB, Pang LX, Guo J, Qi ZM, Shao T, Yue ZX, and Yao X, Sintering Behavior and Dielectric Properties of Ultra-Low Temperature Fired Silver Molybdate                    Ceramics, J. Am. Ceram. Soc., 2014, 97, 3597-3601.  

[88] Zhou D*, Pang LX, Qi ZM, Jin BB, Yao X, Novel ultra-low temperature co-fired microwave dielectric ceramic at 400 degrees and its chemical compatibility with base metal,            Scientific Reports, 2014, 4, 5980.  

[87] Zhou D*, Pang LX, Qi ZM,   X, Crystal Structure and Microwave Dielectric Behaviors of Ultra-Low Temperature Fired x(Ag_0.5Bi_0.5)MoO₄−(1−x)BiVO₄ (0.0 ≤ x ≤ 1.0) Solid          Solution with Scheelite Structure, Inorganic Chemistry, 2014, 53, 9222-9227.

[86] Guo J, Zhou D*, Zou SL, Wang H, Pang LX, and   X, Microwave Dielectric Ceramics Li₂MO₄-TiO₂ (M=Mo, W) with Low Sintering Temperatures, J. Am. Ceram. Soc., 2014,        97[6], 1819–1822.  

[85] Xi HH, Zhou D*, He B, Xie XD, Microwave Dielectric Properties of PbMoO₄ Ceramic with Ultra-Low Sintering Temperature, J. Am. Ceram. Soc., 2014, 97 [5], 1375–1378.

[84] Pang LX, Zhou D*, and Liu WG, Low-Temperature Sintering and Microwave Dielectric Properties of CaMoO₄-Based Temperature Stable LTCC Material, J. Am. Ceram. Soc.,        2014, 97 [7], 2032–2034.  

[83] Zhang YD, Zhou D*, Guo J, Xi HH, He B, Microwave dielectric properties of the (1-x)(Mg_0.95Zn_0.05)TiO₃-x(Ca_0.8Sm_0.43)TiO₃ temperature stable ceramics, Materials Letters       132 (2014) 200–202. 

[82] Guo J, Zhou D, Li Y, Shao T, Qi ZM, Jin BB, and Wang H^*, Structure–property relationships of novel microwave dielectric ceramics with low sintering temperatures:                        (Na_0.5xBi_0.5xCa_1−x)MoO₄, Dalton Trans., 2014, 43, 11888-11896.

[81] He L, Zhou D, Yang HB, Niu YJ, Xiang F, and Wang H^*, Low-Temperature Sintering Li₂MoO₄-Ni_0.5Zn_0.5Fe₂O₄ Magneto-Dielectric Composites for High-Frequency                        Application, J. Am. Ceram. Soc., 2014, 97[8], 2552–2556.  

[80] Guo J, Randall CA, Zhang GQ, Zhou D, Chen YY, Wang H^*, Synthesis, Structure, and Characterization of New Low-Firing Microwave Dielectric Ceramics:                                        (Ca_1-3xBi_2xΦ_x)MoO₄, Journal of Materials Chemistry C, 2014, 2, 7364-7372.  

[79] Zhang GQ, Guo J, He L, Zhou D, Wang H^*, Koruza J, Kosec M, Preparation and Microwave Dielectric Properties of Ultra-low Temperature Sintering Ceramics in K₂O–MoO₃           Binary System, J. Am. Ceram. Soc., 97 [1] 241–245 (2014).  

[78] Xie HD^*, Xi HH, Li F, Chen C, Wang XC, Zhou D, Microwave dielectric properties of Pb₂MoO₅ ceramic with ultra-low sintering temperature, Journal of the European                    Ceramic Society, 2014, 34 [15],  4089-4093.  

2013

[77] Zhou D*, Pang LX, Qu WG, et al., Dielectric behavior, band gap, in situ X-ray diffraction, Raman and infrared study on (1-x)BiVO₄-x(Li_0.5Bi_0.5)MoO₄ solid solution, RSC              Advances, 2013, 3, 5009-5014. 

[76] He L, Zhou D, Xiang F, Chang PP, Li Y, Wang H, A Novel Magnetodielectric Solid Solution Ceramic 0.4LiFe₅O₈–0.6Li₂MgTi₃O₈ with Excellent Microwave Dielectric                     Properties, Journal of the American Ceramic Society, 2013, 96 [10] 3027–3030.

[75] Pang LX, Zhou D*, Wang H, Effect of Ca substitution on phase compositions and dielectric properties of Bi₂O₃-ZnO-Nb₂O₅ pyrochlore ceramics, Ceramic  International,               2013, 39, s673-s676.

[74] Pang LX, Zhou D*, Guo J, Qi ZM, Shao T, Microwave dielectric properties of scheelite structured low temperature fired Bi(In_1/3Mo_2/3)O₄ ceramic, Ceramic International,             2013, 39, 4719-4722.

[73] Guo J, Zhou D, Wang L, Wang H, Shao T, Qi ZM and Yao X, Infrared spectra, Raman spectra, microwave dielectric properties and simulation for effective permittivity of                 temperature stable ceramics AMoO₄-TiO₂ (A=Ca, Sr), Dalton Transactions, 2013, 42, 1483. 

[72] Pang LX, Zhou D, Chang-Long Cai, Wei-Guo Liu, Infrared spectroscopy and microwave dielectric properties of ultra-low temperature firing                                                               (K_0.5La_0.5)MoO₄ ceramics, Materials Letters, 2013, 92, 36-38.

[71] He L, Yang HB, Zhou D, Niu YJ, Xiang F, Wang H, Improved dielectric and magnetic properties of 1-3-type Ni_0.5Zn_0.5Fe₂O₄/epoxy composites for high frequency                             applications, Journal of Physics D-Applied Physics, 2013, 46(12), 125003.

[70] Wu Y, Zhou D*, Guo J, Pang LX, Microwave dielectric properties and low temperature firing of (1-x)Li₂Zn₃Ti₄O₁₂-xLi₂TiO₃ ceramics with B₂O₃-CuO addition,Journal of             Materials Science: Materials in Electronics, 2013, 24(5), 1505-1510.

[69] Wu Y, Zhou D*, Guo J, Pang LX, Microwave dielectric properties and low temperature sintering of Li₂Zn(Ti_1-xSn_x)₃O₈ (x≤0.20) ceramics with B₂O₃-CuO addition, Journal of       Materials Science: Materials in Electronics, 2013, 24(12), 4942-4946.

2012

[68] Zhou D*, Pang LX, Guo J, Qi ZM, Shao T, Yao X, Randall CA, , Phase evolution, phase transition, and microwave Dielectric properties of scheelite structured xBi(Fe_1/3Mo_2/3)O₄-(1-x)BiVO₄ (0.0≤x≤1.0) low temperature firing ceramics, Journal of Materials Chemistry, 2012, 22, 21412.

[67] Zhou D*, Pang LX, Guo J, et al, Phase evolution and microwave dielectric properties of (Li_0.5Bi_0.5)(W_1-xMo_x)O₄ (0.0≤x≤1.0) ceramics with ultra-low sintering                                 temperatures, Functional Materials Letters, 2012, 5(4) 1250042.

[66] Wu XG, Wang H, Chen YH, Zhou D, Synthesis and Microwave Dielectric Properties of Zn₃B₂O₆ Ceramics for Substrate Application, Journal of the American Ceramic Society, 2012, 95(6): 1793-1795.

[65] Dai W, Wang H, Chen SB, Li DC, Zhou D, Effect of point defects on band-gap properties in diamond structure photonic crystals, Journal of Applied Physics, 2012, 111(2).

[64] Pang LX, Liu H, Zhou D, JX Yang, DJ Li, WG Liu,Low-temperature sintering and microwave dielectric properties of Li₃MO₄ (M = Ta, Sb) ceramics, Journal of Alloys and            Compounds, 2012, 525, 22-24.

[63] Guo J, Zhou D, Wang H, Chen YH, Zeng Y, Xiang F, Wu Y, Yao X, Microwave and Infrared Dielectric Response of Temperature Stable (1-x)BaMoO₄-xTiO₂Composite                       Ceramics, Journal of the American Ceramic Society, 2012, 95(1): 232-237. 

[62] Pang LX, Liu H, Zhou D, Sun GB, Qin WG, Liu WG, Microwave dielectric ceramic with intrinsic low firing temperature: BaLa₂(MoO₄)₄, Materials Letters, 2012, 72: 128-               130. 

[61] He L, Zhou D, Yang HB, Guo J, and Wang H, A novel magneto-dielectric solid solution ceramic 0.25LiFe₅O₈–0.75Li₂ZnTi₃O₈ with relatively high permeability and ultra-low           dielectric loss, Journal of the American Ceramic Society, 2012, 95 [12] 3732–3734. 

2011

[60] Zhou D*, Randall CA, Pang LX, Wang H, Guo J, Zhang GQ, Wu Y, Guo KT, Shui L, Yao X, Microwave dielectric properties of (ABi)_1/2MoO₄ (A = Li, Na, K, Rb, Ag) type ceramics with ultra-low firing temperatures, Materials Chemistry and Physics, 2011, 129(3): 688-692.  

[59] Zhou D*, Randall CA, Pang LX, Wang H, Wu XG, Guo J, Zhang GQ, Shui L, Yao X, Microwave Dielectric Properties of Li₂(M²⁺)₂Mo₃O₁₂ and Li₃(M³⁺)Mo₃O₁₂ (M=Zn, Ca, Al, and In) Lyonsite-Related-Type Ceramics with Ultra-Low Sintering Temperatures, Journal of the American Ceramic Society, 2011, 94(3): 802-805. 

[58] Zhou D*, Randall CA, Pang LX, Wang H, Guo J, Zhang GQ, Wu XG, Shui L, Yao X, Microwave Dielectric Properties of Li₂WO₄ Ceramic with Ultra-Low Sintering Temperature, Journal of the American Ceramic Society, 2011, 94(2): 348-350. 

[57] Zhou D*, Qu WG, Randall CA, Pang LX, Wang H, Wu XG, Guo J, Zhang GQ, Shui L, Wang QP, Liu HC, Yao X. Ferroelastic phase transition compositional dependence for solid-solution [(Li_0.5Bi_0.5)_xBi_1-x][Mo_xV_1-x]O₄ scheelite-structured microwave dielectric ceramics, Acta Materialia, 2011, 59(4): 1502-1509. 

[56] Zhou D*, Pang LX, Wang H, Guo J, Yao X, Randall CA, Phase transition, Raman spectra, infrared spectra, band gap and microwave dielectric properties of low temperature firing (Na_0.5xBi_1-0.5x)(Mo_xV_1-x)O₄ solid solution ceramics with scheelite structure, Journal of Materials Chemistry, 2011, 21: 18412-18420.

[55] Zhou D*, Pang LX, Guo J, Wang H, Yao X, Randall CA, Phase Evolution, Phase Transition, Raman Spectra, Infrared Spectra and Microwave Dielectric Properties of Low Temperature Firing (K_0.5xBi_1-0.5x)(Mo_xV_1-x)O₄ Ceramics with Scheelite Related Structure, Inorganic Chemistry, 2011, 50: 12733-12738.

[54] Zhou D*, Pang LX, Guo J, Wu Y, Zhang GQ, Dai W, Wang H, Yao X, New Microwave Dielectric Ceramics BaLn₂(MoO₄)₄ (Ln = Nd and Sm) with Low Loss, Journal of the American Ceramic Society, 2011, 94(9): 2800-2803. 

[53] Zhou D*, Pang LX, Guo J, Zhang GQ, Wu Y, Wang H, Yao X, Low temperature firing microwave dielectric ceramics (K_0.5Ln_0.5)MoO₄ (Ln =Nd and Sm) with low dielectric loss, Journal of the European Ceramic Society, 2011, 31(15): 2749-2752. 

[52] Zhou D*, Pang LX, Guo J, Wu Y, Zhang GQ, Wang H, Yao X, sintering behavior and microwave dielectric properties of novel low temperature firing Bi₃FeMo₂O₁₂ Ceramic, Journal of Advanced Dielectrics, 2011, 1(4): 379-382. 

[51] Pang LX, Zhou D, Ca₃WO₆: a novel microwave dielectric ceramic with complex perovskite structure, Journal of Materials Science-Materials in Electronics, 2011, 22(7): 807-810.

[50] Dai W, Wang H, Wang MJ, Shen ZY, Li DC, Zhou D, Diamond electromagnetic band gap structure based on Bi(Nb_0.992V_0.008)O₄ ceramic, Journal of Materials Science-Materials in Electronics, 2011, 22(4): 422-425. 

[49] Pang LX, Sun GB, Zhou D, Ln₂Mo₃O₁₂ (Ln = La, Nd): A novel group of low loss microwave dielectric ceramics with low sintering temperature, Materials Letters, 2011 65(2): 164-166. 

[48] Guo J, Zhou D, Wang H, et al. Microwave dielectric properties of (1-x)ZnMoO₄-xTiO₂ composite ceramics, Journal of Alloys and Compounds, 2011 509(19): 5863-5865.  

[47] Pang LX, Zhou D, Wang H, et al. Phase evolution and microwave dielectric properties of Bi₃SbO₇ ceramic, Journal of Physics and Chemistry of Solids, 2011 72(7): 882-885. 

[46] Pang LX, Zhou D, Chen YH, et al.Structural and microwave dielectric behavior of (Li_1/4Nb_3/4) substituted Zr_xSn_yTi_zO₄ (x+y+z=2) system, Materials Chemistry and Physics, 2011 125(3): 641-645.  

[45] Wu Y, Zhou D, Guo J, et al. Temperature stable microwave dielectric ceramic 0.3Li₂TiO₃-0.7Li(Zn_0.5Ti_1.5)O₄ with ultra-low dielectric loss, Materials Letters, 2011 65(17-18): 2680-2682. 

2010

[44] Zhou D*, Wang H, Pang LX, Yao X. Low-firing of BiSbO₄ microwave dielectric ceramic with V₂O₅-CuO addition [J]. Materials Chemistry and Physics, 2010, 119: 149-152. 

[43] Zhou D*, Randall C, Wang H, Pang LX, Yao X. Microwave dielectric ceramics in Li₂O-Bi₂O₃-MoO₃ system with ultra low sintering temperatures [J]. Journal of the American Ceramic Society, 2010, 93(4): 1096-1100. 

[42] Zhou D*, Randall C, Baker A, Wang H, Pang LX, Yao X. Dielectric properties of an ultra-low temperature co-firing Bi₂Mo₂O₉ multilayer [J]. Journal of the American Ceramic Society, 2010, 93(5): 1443-1446. 

[41] Zhou D*, Randall CA, Wang H, et al. Ultra-Low Firing High-k Scheelite Structures Based on [(Li_0.5Bi_0.5)_xBi_1-x][Mo_xV_1-x]O₄ Microwave Dielectric Ceramics, Journal of the American Ceramic Society, 2010 93(8): 2147-2150. 

[40] Zhou D*, Wang H, Wang QP, et al. Microwave dielectric properties and Raman spectroscopy of scheelite solid solution [(Li_0.5Bi_0.5)_1-xCa_x]MoO₄ ceramics with ultra-low sintering temperatures, Functional Materials Letters, 2010 3(4): 253-257. 

[39] Pang LX, Zhou D, A low-firing microwave dielectric material in Li₂O-ZnO-Nb₂O₅ system, Materials Letters, 2010 64(22): 2413-2415. 

[38] Pang LX, Wang H, Zhou D, et al. A new temperature stable microwave dielectric with low-firing temperature in Bi₂MoO₆-TiO₂ system, Journal of Alloys and Compounds, 2011 493(1-2): 626-629.  

[37] Liu WH, Wang H, Zhou D, et al. Dielectric Properties of Low-Firing Bi₂Mo₂O₉ Thick Films Screen Printed on Al Foils and Alumina Substrates. Journal of the American Ceramic Society, 2010 93(8): 2202-2206.  

[36] Dai W, Wang H, Wang MJ, Shen ZY, Li DC, Zhou D, Shi JZ, Fabrication of three-dimensional electromagnetic band-gap structure with high-K dielectric ceramics by rapid-   prototyping, Journal of Electroceramics, 2010 25(2-4): 218-222.  

[35] Pang LX, Wang H, Zhou D, et al. Low-temperature sintering and microwave dielectric properties of TiO₂-based LTCC materials, Journal of Materials Science-Materials in Electronics, 2010 21(12): 1285-1292.  

[34] Pang LX, Zhou D, Microwave Dielectric Properties of Low-Firing Li₂MO₃ (M = Ti, Zr, Sn) Ceramics with B₂O₃-CuO Addition, Journal of the American Ceramic Society, 2010 93(11): 3614-3617.  

[33] Pang LX, Wang H, Zhou D, et al. Phase evolution, Raman spectroscopy and microwave dielectric behavior of (Li_1/4Nb_3/4) doped ZrO₂-TiO₂ system, Applied Physics a-Materials Science & Processing, 2010 100(4): 1205-1209.  

[32] Pang LX, Wang H, Zhou D, et al. Sintering behavior and microwave dielectric properties of Ba_6-3xNd_8+2xTi₁₈O₅₄ (x=2/3) ceramics coated by H₃BO₃-TEOS sol-gel, Materials Chemistry and Physics, 2010 123(2-3): 727-730. 

[31] Dai W, Wang H, Zhou D, et al. The Ultra-Wide Band Gap Property Induced by Lattice Period Gradually Changing in Three-Dimensional Photonic  , Journal of the American Ceramic Society, 2010 93(12): 3980-3982. 

2009

[30] Zhou D, Wang H*, Yao X, Pang LX, Chen YH. Sintering behavior, phase evolution and microwave dielectric properties of Bi{Sb_1-x(Nb_0.992V_0.008)_x}O₄ ceramics[J]. Materials Chemistry and Physics, 2009, 113:265-268. 

[29] Zhou D, Wang H*, Pang LX,   X, Wu XG. Low temperature firing of BiSbO₄ microwave dielectric ceramic with B₂O₃-CuO addition[J]. Journal of the European Ceramic Society, 2009, 29: 1543-1546. 

[28] Zhou D*, Pang LX, Yao X, Wang H. Influence of sintering process on the microwave dielectric properties of Bi(V_0.008Nb_0.992)O₄ ceramics[J]. Materials Chemistry and Physics, 2009, 115: 126-131. 

[27] Zhou D*, Wang H, Pang LX, Randall C, Yao X. Bi₂O₃-MoO₃ binary system: an alternative ultralow sintering temperature microwave dielectric[J]. Journal of the American Ceramic Society, 2009, 92(10): 2242-2246. 

[26] Zhou D*, Randall C, Wang H, Pang LX, Yao X. Microwave dielectric properties trends in a solid solution (Bi_1-xLn_x)₂Mo₂O₉ (Ln=La,Nd, 0.0≤x≤0.2) system[J]. Journal of the American Ceramic Society, 2009, 92(12): 2931-2936. 

[25] Zhou D, Pang LX, Wang H*, Yao X. Phase composition and phase transformation in Bi(Sb,Nb,Ta)O₄ system[J]. Sciences, 2009, 11: 1894-1897. 

[24] Pang LX, Wang H, Zhou D, Yao X. Raman spectroscopy and microwave dielectric properties of Zr_1-x(Li_1/4Nb_3/4)_xTiO₄ ceramics[J]. Japanese Journal of Applied Physics, 2009, 48(5): 051403. 

[23] Pang LX, Wang H, Chen YH, Zhou D, Yao X. Microstructures and microwave dielectric properties of low-temperature sintered Ca₂Zn₄Ti₁₅O₃₆ ceramics[J]. Journal of Materials Science-Materials in Electronics, 2009, 20(6):528-533. 

[22] Pang LX, Wang H, Zhou D, Yao X. Sintering behavior, structures and microwave dielectric properties of a rutile solid solution system: (A_xNb_2x)Ti_1-3xO₂ (A=Cu, Ni)[J]. Journal of Electroceramics, 2009, 23(1): 13-18. 

2008

[21]  Zhou D, Wang H, Yao X, Liu Y. Microwave dielectric properties of low-firing BiNbO₄ ceramics with V₂O₅ substitution[J]. Journal of Electroceramics,  2008, 21(1-4): 469-472.  

[20]  Zhou D, Wang H,   X, Pang LX. Microwave dielectric properties of low temperature firing Bi₂Mo₂O₉ ceramic[J]. Journal of the American Ceramic  Society, 2008, 91(10): 3419-3422.  

[19]  Zhou D, Wang H,   X, Pang LX, Wu XG. Microwave dielectric characterization of a Li₃NbO₄ ceramic and its chemical compatibility with silver [J]. Journal of the American Ceramic Society, 2008, 91(12): 4115-4117.  

[18]  Zhou D, Wang H,   X, Pang LX. Sintering behavior and microwave dielectric properties of Bi₂O₃-ZnO-Nb₂O₅-based ceramics sintered under air and N₂ atmosphere [J]. Ceramics International, 2008, 34: 901-904. 

[17] Zhou D, Wang H, Yao X. Microwave dielectric properties and co-firing with copper of (Bi_1-xCu_x)(Nb_1-xW_x)O₄ ceramics [J]. Ceramics International, 2008, 34: 929-932.

[16]  Zhou D, Wang H, Yao X, Pang LX, Zhou HF. Nanopowder preparation and dielectric properties of a Bi₂O₃-Nb₂O₅ binary system prepared by the high-energy ball-milling method[J]. Journal of the American Ceramic Society, 2008, 91(1): 139-143.

[15]  Zhou D, Wang H,   X, Pang LX. Dielectric behavior and cofiring with silver of monoclinic BiSbO₄ Ceramic [J]. Journal of the American Ceramic Society, 2008, 91(4): 1380-1383.

[14]  Zhou D, Wang H,   X, Pang LX. Sintering behavior and microwave dielectric properties of Bi₃(Nb_1-xTa_x)O₇ solid solutions [J]. Materials Chemistry and Physics, 2008, 110: 212-215.  

[13]  Zhou D, Wang H,   X, Pang LX. Sintering behavior, phase evolution, and microwave dielectric properties of Bi(Sb_1-xTa_x)O₄ ceramics [J]. Journal of the American Ceramic Society, 2008, 91(7): 2228-2231.

[12] Zhang L, Wang H,   X, Zhou D. The effect of sintering atmosphere on V₂O₅ substituted BiNbO₄ microwave ceramics [J]. Journal of Electroceramics,2008, 21(1-4): 465-468.

[11] Pang LX, Wang H, Zhou D, Zhou HF, Yao X. Low-temperature firing and microwave dielectric properties of Ca[(Li_1/3Nb_2/3)_0.8Ti_0.2O_3-δ ceramicswith ZnB₂O₄   glass addition [J]. International Journal of Applied Ceramic Technology, 2008, 5(4): 341-346. 

[10] Pang LX, Wang H, Zhou D, Yao X. Sintering behavior, structures, and microwave dielectric properties of (Li_xNb_3x)Ti_1-4xO₂ [J]. Journal of the American Ceramic Society, 2008, 91(9): 2947-2951.

[9] Zhou HF, Wang H, Zhou D, Pang LX, Yao X. Effect of ZnO and B₂O₃ on the sintering temperature and microwave dielectric properties of LiNb_0.6Ti_0.5O₃ ceramics [J]. Materials Chemistry and Physics, 2008, 109(2-3): 510-514. 

 

2007 

[8]  Zhou D, Wang H, Yao X. Sintering behavior and dielectric Properties of Bi₃NbO₇ ceramics prepared by mixed oxides and high-energy ball-milling methods [J]. Journal of the American Ceramic Society, 2007, 90(1): 327-329.  

[7]  Zhou D, Wu W, Wang H, Jiang YS,   X. The two element antennas using BiNbO₄ ceramics as the substrate [J]. Materials Science and Engineering A, 2007, 460-461: 652-655. 

[6]  Zhou D, Wang H,   X, Wei XY, Xiang F, Pang LX. Phase transformation in BiNbO₄ ceramics [J]. Applied Physics Letters, 2007, 90:172910. 

[5]  Zhou D, Wang H, Yao X. Microwave dielectric properties and co-firing of BiNbO₄ ceramics with CuO substitution [J]. Materials Chemistry and Physics, 2007, 104:397-402. 

[4]  Zhou D, Wang H, Zhou HF, Xie XJ,     X, Cheng YH. Preparation of Sb₃Nb₃O₁₃ powders using molten salt method [J]. Journal of Materials Science, 2007, 42:  8387-8390.  

[3]  Zhou D, Wang H,     X, Pang LX. Microwave dielectric properties and co-firing of BiNbO₄ ceramics with CuO-WO₃ substitution [J]. Materials Science and Engineering B, 2007, 142: 106-111. 

[2]  Zhou D, Wang H, Yao X. Layered complex structures of Bi₂(Zn_2/3Nb_4/3)O₇ and BiNbO₄ dielectric ceramics [J]. Materials Chemistry and Physics, 2007, 105: 151- 153.  

 

2006 

 [1]  Kamba S, Wang H, Berta M, Kadlec F, Petzelt J, Zhou D, Yao X. Correlation between infrared, THz and microwave dielectric properties of vanadium doped antiferroelectric BiNbO₄ [J]. Journal of the European Ceramic Society, 2006, 26: 2861-2865. 

 

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