徐谛明

教育背景

2014年10月-2018年07月

自然哲学博士，无机固态化学，牛津大学

2010年09月-2014年06月

理学学士，化学，南京大学

工作经历

2026年01月-至今

副教授，电子与信息学部电子科学与工程学院，西安交通大学

2022年02月-2025年12月

助理教授，电子与信息学部电子科学与工程学院，西安交通大学

2018年09月-2021年12月

国际引进博士后，化学与分子工程学院，北京大学

荣誉奖励

2024年        入选第九届中国科学技术协会人才托举工程（中国电子学会）

2022年        陕西省秦创原引用高层次创新创业人才

2024年        入选陕西省教学案例《洞悉材料微观参数之离子半径》（第四完成人）

2024年        中国国际大学生创新大赛陕西赛区铜奖（第二指导教师）

2023年       第九届中国国际“互联网+”大学生创新创业大赛陕西赛区铜奖（第一指导教师）

2023年        第九届中国国际“互联网+”大学生创新创业大赛陕西赛区金奖（第二指导教师）

态度端正：依然努力学习，什么方向都需要懂一些

能征善战：曾有一个月写完7篇SCI论文的战绩

思如泉涌：需要战友来探索实现很多想法

平易近人：超好沟通，典型e人，什么都能聊

1、5G/6G用微波介质材料的开发研究

2、储能用电容器电介质材料的开发研究

3、介电材料性能与结构调控机理研究

4、人工智能技术的高通量材料筛选方法

ORCID：0000-0002-7320-0009

[1]Ultralow Loss and High Tunability in a Non-perovskite Relaxor Ferroelectric. R. Li#, D. Xu#, M. Avdeev, L. Zhang, X. Chen, G. Gou, D. Wang, W. Liu and D. Zhou*,Adv. Funct. Mater., 2022, 2210709.

[2] Design and Fabrication of a C-Band Dielectric Resonator Antenna with Novel Temperature-Stable Ce(Nb_1–xV_x)NbO₄ (x = 0–0.4) Microwave Ceramics. F. F. Wu, D. Zhou*, C. Du, D. Xu*, R. Li, L. Zhang, F. Qiao, Z. Q. Shi, M. A. Darwish, T. Zhou, H. Jantunen, and I. M. Reaney*, ACS Appl. Mater. Interfaces, 2022, 14, 48897.

[3]Design and Fabrication of a Satellite Communication Dielectric Resonator Antenna with Novel Low Loss and Temperature-Stabilized (Sm_1–xCa_x)(Nb_1–xMo_x)O₄ (x = 0.15–0.7) Microwave Ceramics. F. Wu, D. Zhou*, C. Du, D. Xu, R. Li, Z. Q. Shi, M. A. Darwish, T. Zhou and H. Jantunen*, Chem. Mater., 2023, 35, 104.

[4]Novel Method to Achieve Temperature-Stable Microwave Dielectric Ceramics: A Case in the Fergusonite-Structured NdNbO₄ System. D. Zhou*, L. Zhang, D. Xu, F. Qiao, X. Yao, H. Lin, W. Liu, L. Pang, F. Hussain, M. A. Darwish, T. Zhou, Y. Chen, Q. Liang, M. Zhang, and I. M. Reaney*, ACS Appl. Mater. Interfaces, 2023, 15, 19129.

[5]Vertically stacked heterostructures of MXene/rGO films with enhanced gradient impedance for high-performance microwave absorption. X. Li#, D. Xu#, D. Zhou*, S. Pang, C. Du, M. A. Darwish, T. Zhou, S. Sun, Carbon, 2023, 208, 374.

[6]Magnetic array vertically anchored on flexible carbon cloth with “magical angle” for the increased effective absorption bandwidth and improved reflection loss simultaneously. X. Li, D. Xu, D. Zhou*, S. Pang, C. Du, M. A. Darwish, T. Zhou, S. K. Sun, Carbon, 2023, 210, 118046.

[7]β-Ga₂O₃: ultralow-loss and low-permittivity dielectric ceramic for high-frequency packaging substrate. W. Wang, C. Du, X. Wang, D. Xu*, H. S. Qiu, B. B. Jin, Z. Q. Shi, F. Hussain, M. A. Darwish, T. Zhou, Y. W. Chen, Q. X. Liang, M. R. Zhang and D. Zhou*, Inorg. Chem. Front., 2023,10, 3723.

[8] Hybrid improper ferroelectricity and phase transition behavior of Li₂Nd₂Ti₃O₁₀ ceramics with A-site ordered triple-layer Ruddlesden-Popper structure. B. H. Zhang#, D. Xu#, R. Z. Guo, L. Liu, X. Q. Liu*, X. M. Chen, J. Materiomics,2023, 10, 145.

[9] Novel B-site Scheelite Structure Ceramic Bi(Ge_0.5Mo_0.5)O₄ and Its Dielectric Properties.D. Xu, H. Zhang, L. Pang, F. Hussain, T. Zhou, S. K. Sun, Z. Chen and D. Zhou*, J. Am. Ceram. Soc., 2023, 106, 6675.

[10] Introducing large-radius elements in layered perovskite for low-voltage lithium storage. X. Li, D. Xu, D. Zhou*, H. Nan, S. Pang, M. A. Darwish, T. Zhou, J. Mater. Chem. A, 2023, 11, 14249.

[11] A high-temperature performing and near-zero energy loss lead-free ceramic capacitor. D. Li, D. Xu*, W. Zhao, M. Avdeev, H. Jing, Y. Guo, T. Zhou, W. Liu, D. Wang and D. Zhou*,Energy Environ. Sci.,2023, 16, 4511.

[12] Broad-high operating temperature range and enhanced energy storage performances in lead-free ferroelectrics. W. Zhao, D. Xu*, D. Li, M. Avdeev, H. Jing, M. Xu, Y. Guo, D. Shi, T. Zhou, W. Liu, D. Wang, D. Zhou*, Nat. Commun., 2023, 14, 5725.

[13] Low-Permittivity and Low-Temperature Cofired BaSO₄–BaF₂ Microwave Dielectric Ceramics for High-Reliability Packaged Electronics. W. Wang, M. Shehbaz, X. Wang, C. Du, D. Xu*, Z.-Q. Shi, M. A. Darwish, H.-S. Qiu, B.-B. Jin, T. Zhou,Y.-W. Chen, Q.-X. Liang, M.-R. Zhang, and D. Zhou*,ACS Appl. Mater. Interfaces, 2023, 15, 51453.

[14] Significantly enhanced energy storage density in lead-free barium strontium titanate-based ceramics through a cooperative optimization strategy.J.-J. Ren, D. Xu*, Da Li, W.-C. Zhao, M.-K. Xu, Z.-Q. Shi, T. Zhou, H.-X. Lin, D. Zhou*, J. Mater. Chem. C, 2023,11, 16739.

[15] Microwave dielectric properties of (Na_0.5Bi_0.5)MoO₄–BaMoO₄ composite ceramics with ultralow sintering temperature. A. R. H. Alzakree, C.-H. Wang, M. Shehbaz, W. Wang, D. Xu, C. Du, D. Zhou*, J. Am. Ceram. Soc., 2024, 107,4738.

[16] Excellent Energy Storage Performance Achieved in Sr(Sc_0.5Nb_0.5)O₃-Doped Bi_0.5Na_0.5TiO₃-Based Lead-Free Relaxor Ferroelectric Ceramics. J. Liu, D. Li, W. Zhao, D. Xu, Z. Shi, W. Liu, J. Su, T. Zhou*, G. Chen, and D. Zhou*, ACS Appl. Energy Mater., 2024, 7, 2030.

[17] Effect of B-site complex substitutions on orthorhombic distortion and microwave dielectric properties of Ca(Zr_0.95Ti_0.05)O₃ perovskites. X. Wang, T. Zhou*, W. Wang, Z. Xi, D. Xu, C. Du, X.-G. Yao, H.-X. Lin, H. Xia, B. Jin, Y. Pang, H. Zhang, C. Liang and D. Zhou*, J. Mater. Chem. C, 2024, 12, 3124.

[18] Optimized energy storage performance in (Ba_0.8Sr_0.2)TiO₃-based ceramics via Bi(Zn_0.5Hf_0.5)O₃-doping. J.-J. Ren, D. Xu*, Q.-Q. Ma, D. Li, W.-C. Zhao, Z.-T. Wang, T. Zhou, W.-F. Liu and D. Zhou*, J. Mater. Chem. C, 2024, 12, 6239.

[19] Improved energy storage properties achieved in NaNbO₃-based relaxor antiferroelectric ceramics via anti-parallel polar nanoregion design. Z. Wang, D. Li, W. Liu, X. Liang, W. Zhao, J. Liu, J. Ren, T. Zhou, D. Xu, W. Liu and D. Zhou*,J. Mater. Chem. A, 2024, 12, 19551.

[20]Millimeter Wave Dielectric Resonator Antenna Using High Quality Factor Temperature Stable Dielectric Ceramic Composite K18 for 5G Applications. M. Shehbaz, C. Du, R. Li, W. Wang, A. R. H. Alzakree, X.-G. Yao, H. Peng, H.-X. Lin, Z.-Q. Shi, D. Xu, S. Xia, Y.-Q. Pang* and Di Zhou*,ACS Appl. Electron. Mater., 2024, 6, 6120.

[21] Effect of LiF and LBSCA glass on the microwave dielectric properties of 0.5BaCuSi₄O₁₀–0.5BaCuSi₂O₆-based ceramics for LTCC applications. Y. Lou, W. Wang, D. Xu, C. Du, X. Wang, F. Hussain, M. A. Darwish, T. Zhou, Y.-W. Chen, Q.-X. Liang, M.-R. Zhang, Y.-Q. Pang, D. Zhou*,J. Am. Ceram. Soc., 2024, 107, 6964.

[22]Giant dielectric tunability in ferroelectric ceramics with ultralow loss by ion substitution design. R. Li, D. Xu*, C. Du, Q. Ma, F. Zhang, X. Liang*, D. Wang*, Z. Shi, W. Liu and D. Zhou*, Nat. Commun., 2024, 15, 3754.

[23] 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. F.-F. Wu, D. Zhou*, C. Du, D. Xu, Z.-Q. Shi, M. A. Darwish, T. Zhou, S.-K. Sun, X.-G. Yao, H.-X. Lin, M.-R. Zhang, Q.-X. Liang, Y.-W. Chen, G. Chen, H. Jantunen*, Appl. Mater. Today, 2024, 38, 102222.

[24] Microwave dielectric properties, vibrational spectrum, and antenna design of a novel melilite-type Ba₂CoSi₂O₇ ceramic. Z.-Y. Liu, W. Wang, D. Xu, C. Du, X. Wang, G.-Q. He, F. Hussain, T. Zhou, B.-B. Jin, K.-H. Zhou, J. Li, C. Liang, D. Zhou*, J. Am. Ceram. Soc., 2024, 107, 8342.

[25] Low-permittivity BaCuSi₄O₁₀-based dielectric Ceramics: An available solution to connect low temperature cofired ceramic technology and millimeter-wave communications. Wei Wang, X. Wang, Ji. Bao, J. Jiang, Z. Fang, B. Jin, Z. Shi, M. A. Darwish, Y. Chen, Q. Liang, M. Zhang, D. Xu, C. Du, D. Zhou*, Chem. Eng. J., 2024, 494, 153172.

[26] NaNbO₃基无铅储能介质陶瓷研究进展. 王震涛, 李达, 赵维琛, 刘津男, 徐谛明, 周迪*, 硅酸盐学报, 2024, 52, 1460.

[27] Low temperature sintering and improvement of temperature Stability of Ba₃P₄O₁₃ microwave dielectric ceramics by BCB additions. C.-H. Wang, W. Wang, D. Xu, A. R. H. Alzakree, F. Hussain, M. A. Darwish, T. Zhou, Y.-W. Chen, Q.-X. Liang, M-R Zhang, Y. Wu, D. Zhou*, Mater. Res. Bull., 179, 112964.

[28] Global-optimized energy storage performance in multilayer ferroelectric ceramic capacitors. D. Li, Z. Liu, W. Zhao, Y. Guo, Z. Wang, D. Xu*, H. Huang*, L.-X. Pang, T. Zhou, W.-F. Liu*, D. Zhou*,Nat. Commun., 2025, 16, 188.

[29] Microwave dielectric properties of temperature-stable (Na_0.5Bi_0.5)MoO₄–SrMoO₄ ceramics sintered at ultra-low temperature. A. R. H. Alzakree, C.-H. Wang, M. Shehbaz, W. Wang, M. A. Darwish, T. Zhou, D. Xu, C. Du, D. Zhou*, J. Am. Ceram. Soc., 2025, 108, e20504.

[30] Rational optimizations of high K microwave dielectric ceramic Bi₂(Li_0.5Ta_1.5)O₇ toward LTCC applications. D. Xu, H. Zhang, L. Pang, F. Hussain, T. Zhou, S.-K. Sun, Z. Chen, D. Zhou*, J. Am. Ceram. Soc., 2025, 108, e20316.

[31] Temperature stable (1-x)BaAl₂Si₂O₈-xBa₃V₂O₈ (0.2 ≤ x ≤ 0.5) microwave dielectric composite ceramics for LTCC applications. W. Wang, Q. Wang, D. Xu, Z. Shi, T. Guo, F. Hussain, M. A. Darwish, T. Zhou, Y. Chen, Q. Liang, M. Zhang, D. Zhou*, J. Eur. Ceram. Soc., 2025, 45, 117042.

[32]P⁵⁺- Enhanced Novel Samarium Niobate Ultralow-Loss Microwave Ceramics as Dielectric Resonator for X-Band Antenna Applications. F.-F. Wu, R. Sun, C. Du, D. Xu, B.-B. Jin, C. Li, H. Jantunen, D. Zhou*, Adv. Funct. Mater., 2025,35, 2421225.

[33] LiMSiO₄ (M = Ga, Sc and Y): Low-permittivity and high thermal conductivity microwave dielectric ceramics for millimeter-wave communications. W. Wang, J. Bao, C. Wang, G. He, X. Wang, D. Xu, B. Jin, Z. Shi, M. A. Darwish, Y. Chen, Q. Liang, M. Zhang, D. Zhou*, J. Mater. Sci. Technol., 2025, 225, 288.

[34] High energy storage density achieved in polymer composites by hierarchical interface engineering design. Y. Liu, J. Qian, Y. Guo, W. Zhao, T. Guo, D. Xu, Z. Wang, G. He, J. Zhai, Y. Zhou, W. Liu, D. Zhou*, Chem. Eng. J., 2025, 505, 159343.

[35] All Ceramic Wideband Dielectric Patch Antenna Using Temperature-Stable High-Permittivity Ba_4.5(Sm_0.8La_0.2)₉Ti₁₈O₅₄ Microwave Dielectric Ceramic for 5G Applications. M. Shehbaz, C. Du, M. W. Niaz, X.-G. Yao, H. Peng, H.-X. Lin, Z.-Q. Shi, D. Xu, S. Xia, Y.-Q. Pang, D. Zhou*, Adv. Eng. Mater., 2025,27, 2402519.

[36] Ultra-high energy storage in lead-free NaNbO₃-based relaxor ceramics with directional slush-like polar structures design. Z. Wang, D. Li, W. Liu, L. He*, D. Xu*, J. Liu, J. Ren, X. Wang, Y. Liu, G. He, J. Bao, Z. Fang, G. Yan, X. Liang, T. Zhou, W. Zhao*, W. Liu, D. Wang*, D. Zhou*, Nat. Commun., 2025, 16, 2892.

[37] Competing Octahedral Modes in the Hybrid Improper Ruddlesden–Popper Ferroelectric Ln₂SrSc₂O₇. Y. Wei, Z. Guo, Z. Zhang, J. Lin, D. Xu*, Y. Huang, X.-Z. Lu, X.-Q. Liu*, X.-M. Chen,Chem. Mater., 2025, 37, 4047.

[38] Dielectric tunability of Ba_0.6Sr_0.4TiO₃–Li₂Mg₃SnO₆ ceramics with ultralow loss.D. Xu, H. Zhang, W. Wang, R. Li, S. Ma, T. Zhou, W. Liu, D. Zhou*,J. Am. Ceram. Soc., 2025, 108, e20316.

[39] Accelerating Low-k Dielectric Material Discovery: From Graph Machine Learning to Synthesis. Z.-C. Xi, X. Wang, C.-H. Wang, W. Wang, J. Bao, D. Xu*, G.-Q. He, T. Zhou, G.-H. Chen, S. Xia, D. Zhou*,ACS Appl. Mater. Interfaces, 2025, 17, 40743.

[40]Advanced stability and energy storage capacity in hierarchically engineered Bi_0.5Na_0.5TiO₃-based multilayer capacitors.W. Zhao, Z. Liu, D. Xu*, G. Wang, D. Li, J. Liu, Z. Wang, Y. Guo, J. Ren, T. Zhou*, L. Pang, H. Yang, W. Liu*, H. Huang*, D. Zhou*, Nat. Commun., 2025, 16, 2892.

[41] Near-Zero Energy Dissipation Multilayer Ceramic Capacitors via Inhomogeneous Polarization Design. J. Liu, W. Zhao*, J. Ren, W. Liu, D. Li, Z. Wang, Y. Liu, W. Liu, T. Zhou, D. Xu*, G. Chen, K.-B. Tan, D. Zhou*,Small, 21, 501062.

[42] Advancing microwave dielectric properties by structural manipulation in BaZrO₃-Ca(Mg_1/3Nb_2/3)O₃ system.X. Wang, K. Zhang, Z. Xi, D. Xu*, W. Wang, J. Bao, K. Zhou, J. Li, C. Liang, T. Zhou, D. Liu, S. Xia, K. B. Tan, D. Zhou*, Appl. Mater. Today, 2025, 44, 102711.

[43] Anisotropic mPPO/TiO₂ composites with enhanced permittivity and thermal conductivity via planar and uniaxial orientation strategies. X. Li, X. Yao, H. Peng*, H. Lin, W. Liu, T. Zhou, D. Xu, X. Li, D. Zhou*, J. Alloy. Compd., 2025, 1024,180179.

[44] Structural and magnetic properties of HoFeCuGe₄O₁₂ with a metamagnetic transition behavior. D. Xu, Z. Liu, X. Li, M. Avdeev, K.-H. Zhou, J. Li, K. B. Tan, T. Zhou, D. Zhou, Mater. Lett., 2025, 393, 138585.

[45] A simple surface engineering approach to enhance the Schottky barrier of polymer dielectrics for superior energy storage performance. T. Liu, Y. Liu, J. Qian, J. Ren, J. Zhai, T. Zhou*, Y. Zhou, G.-W. Yan, D. Xu, W. Liu*, Di Zhou*, J. Mater. Chem. A, 2025, 13, 26279.

[46] Advancements in microwave dielectric ceramics with K20 for 5G/6G communication systems: a review. G.-Q. He, J. Miao, F.-F. Wu, W. Wang, J. Bao, J.-P. Jiang, D.-W. Liu, M. A. Darwish, T. Zhou, D. Xu, S. Xia*, K. B. Tan, D. Zhou*, J. Mater. Chem. C, 2025, 13, 15746.

[47] Dielectric tunability performance and structural evolution of Ba_0.6Sr_0.4TiO₃-based ceramics by BaCuSi₄O₁₀-BaCuSi₂O₆ modification. D. Xu, H. Zhang, W. Wang, R. Li, T. Zhou, W. Liu, D. Zhou*, Mater. Lett., 2025, 401, 139286.

[48] Microwave dielectric properties and low-temperature sintering of (1-x) BaTi4O9-xBaMoO4 composite ceramics. L.-X. Pang*, H. Li, W.-B. Li, Q. Zhang, Y.-W. Chen, M.-R. Zhang, D. Xu, K. B. Tan, D. Zhou*,J. Alloy. Compd., 2025, 1045, 184690.

[49] Temperature-Stable (1−x)LaAlO₃−xNa_0.5La_0.5TiO₃ Perovskite Ceramics with Ultra-Low Microwave Dielectric Loss. W.-B. Li, L.-X. Pang*, H. Li, W. Wang, D. Xu, T. Zhou, Q.-X. Liang, M.-R. Zhang, D. Zhou*, ACS Appl. Electron. Mater., 2025, 7, 22, 10464.

[50] A comprehensive study on low temperature sintering and microwave/terahertz dielectric properties of BaO-P2O5 binary ceramics. C.-H. Wang, K.-H. Zhang, W. Wang, J. Bao, J.-P. Jiang, K.-H. Zhou, J. Li, C. Liang, D.-W. Liu, M. A. Darwish, T. Zhou, D. Xu, S. Xia, K. B. Tan, Di Zhou*, J. Mater. Chem. C, 2025, 13, 14843.

[51] Cationic Nano Single Crystals: From In Situ Structural Determination to Synergistic Photoimmunotherapy. P. Zhang, Q. Shen, D. Xu*, J. Yang, X. Luo, P. Zhou, J. Wang, Y. Xu, L. Meng, D. Dang*,J. Am. Chem. Soc., 2025, 147, 41973

[52] Highly enhanced dielectric tunable performance in Ba_0.6Sr_0.4TiO₃ ceramics via Li₂ZnTi₃O₈ addition. D. Xu, W. Wang, R. Li, Z. Fang, S. Ma, H. Zhang, T. Zhou, W. Liu, D. Zhou*, J. Eu. Ceram. Soc., 2026, 46, 117775.

[53] Low-Temperature Sintered Ba₁₆ZrNb₁₂O₄₈-BaWO₄ Composite Ceramics with Near-Zero τf and Enhanced Q×f for LTCC Applications. Z. Yu, C.-H. Wang, X. Wang, G. He; P. Ma, J. Bao, Z. Fang, D. Xu, L.-X. Pang*, T. Zhou, K. B. Tan, D. Zhou*, J. Eu. Ceram. Soc., 2026, 46, 117775.

[54] High microwave dielectric performance and applications in antenna of novel Li₇La₃Zr₂O₁₂ ceramics.G.-Q. He, C. Du, Z.-T. Wang, J. Bao, Z. Fang, C.-H. Wang, Z.-C. Xi, M. A. Darwish, T. Zhou, D. Xu, S. Xia, Y.-Z. Wen, K. B. Tan*, D. Zhou*, J. Am. Ceram. Soc., 2026, 109, e70425.

[55] Materials Engineering in Microwave Absorbers: Recent Advances and Prognosis. M. Shehbaz, X. Li*, C. Du, D. Xu, X.-G. Yao, H.-X. Lin, T. Zhou, Z.-Q. Shi, S. Xia, D. Zhou*,J. Mater. Chem. C, 2026, Advance Article. doi.org/10.1039/D5TC02882E.

[56] Superior dielectric energy storage performance at elevated temperatures enabled by precisely tailored MgO NPLs distribution in tri-layer polymer composites. Y. Han, X. Li*, Y. Liu, J. Qian, J. Liu, D. Xu, W. Zhao, H. Zhou, J. Zhai*, T. Zhou*, Y. Zhou, W. Liu*, D. Zhou*, Nano Energy, 2026, 147, 111587.

[57] Interlayer-directed multilevel trap engineering for enhanced energy storage in PET dielectric films. T. Liu, J. Liu, Y. Liu, J. Qian, J. Zhai, Y. Zhou*, T. Zhou, G.-W. Yan, D. Xu, K. B. Tan*, W. Liu, D. Zhou*, Nano Energy, 2026, 147, 111613.

[58]Enhanced Energy Storage Performance Through Electron-Hole Pair Formation in Polymer Matrices Doped with P-Type Molecular Semiconductor. T. Liu, Y. Liu, J. Qian, J. Zhai*, T. Zhou, Y. Zhou, D. Xu, W. Liu, D. Zhou*, Adv. Funct. Mater., 2026,Advance Article.doi.org/10.1002/adfm.202516202.

[59]Novel Temperature-Stable (1-x)Ba₃V₂P₃O₁₅-xBaV₂O₆ Composite Ceramics with Ultralow Sintering Temperature and Low Dielectric Loss for Dielectric Resonator Antenna Applications. C.-H. Wang, K.-H. Zhang, J. Bao, J.-P. Jiang, D. Xu, C. Du, L.-X. Pang*, T. Zhou*, K. B. Tan*, D. Zhou*, Adv. Funct. Mater., 2026,Advance Article.doi.org/10.1002/adfm.202522167.

[60]BaSc₂O₄: A Novel AB₂O₄-Type Low-k Microwave Dielectric Ceramic with Giant Positive τf for 5G/6G Frequency Compensation. G.-Q. He, C. Du, Z. Wang, Z. Fang, W. Wang, Z. Xi, C. Wu, S. Ma, M. A. Darwish, T. Zhou, D. Xu, S. Xia, Y. Wen, K. B. Tan*, D. Zhou*, Adv. Funct. Mater., 2026,Advance Article.doi.org/10.1002/adfm.202528138.

[61] Multilevel Heterointerface Engineering Breaks the Trap-Barrier Trade-Off in High-Energy-Density Polymer Dielectrics. Y. Liu, Z. Shao, J. Qian, T. Guo, J. Bao, D. Xu, W. Zhao, Z. Wang, Z. Huang, J. Ren, J. Liu, Z. Liu, J. Zhai*, Y. Zhou*, Z. Liu*, T. Zhou*, G. Yan, J. Su, W. Liu, W. Liu*, J. Jacas, J. R. M. Lleonart, A. Cabot, and D. Zhou*, Adv. Mater., 2026, Advance Article.doi.org/10.1002/adma.202517624.

[1] 国家自然科学基金，青年基金，主持；

[2] 国家自然科学基金，面上基金，参与；

[3] 国家自然科学基金，面上基金，参与；

[4] 国家重点研发计划，参与；

[5] 科学技术部国际科技合作中心，政府间国际科技创新合作，参与；

[6] 科学技术部，国家重大科研仪器研制项目，参与；

[7] 陕西省科学技术厅，秦创原引用高层次创新创业人才项目，主持；

[8] 陕西省科学技术厅，陕西省重点研发计划，参与；

[9] 陕西省科学技术厅，陕西省重点研发计划，参与；

[10]中国科学技术协会, 第九届青年人才托举工程项目, 主持；

[11] 陕西省教育厅，政企联合资助项目（秦创原总窗口专项），主持；

[12] 西安交通大学，重点科研平台青年学术骨干支持-实验室青年骨干培植，主持；

[13] 西安交通大学，团队和人才支持专项-学科交叉团队，参与；

[14] 西安交通大学，团队和人才支持专项-学科交叉团队，参与；

[15] 西安交通大学，重点科研平台青年学术骨干支持-实验室青年骨干培植，参与。