Bingcheng Luo

Professor Luo Bingcheng, a renowned doctoral supervisor and a national-level young talent, spearheads the cutting-edge research team focused on Low-Carbon Technology and Energy Conversion Physics.

He earned his Ph.D. from the School of Materials Science and Engineering at Tsinghua University in 2018, under the distinguished mentorship of Academician Li Longtu and Professor Wang Xiaohui. Post-doctorate, he furthered his academic pursuits at the Department of Engineering and the Cambridge Graphene Centre at the University of Cambridge, collaborating with Professor Andrea Ferrari, a Fellow of the Royal Academy of Engineering. In 2021, he was appointed as a distinguished professor at the Department of Applied Physics, China Agricultural University.

Professor Luo has established and currently leads the “Low-Carbon Technology and Energy Conversion Physics” innovative team. He has played a pivotal role in directing and participating in significant research projects, including those funded by the National Natural Science Foundation of China and the European Union’s Horizon 2020 Graphene Flagship. His research accomplishments span the prediction of novel materials, the development of dielectric ferroelectric materials for information functions, and their applications in energy and agriculture. His scholarly contributions include more than 90 SCI-indexed publications in prestigious journals such as Nature Communications, PNAS, and Angewandte Chemie, with his works cumulatively cited over 3700 times. Moreover, he has secured two national invention patents. His achievements have earned him a place on the global list of top 2% scientists, the First Prize of the China Science and Technology Promotion Association, and the status of a Wiley China Open Science Highly Cited Author.

In his role as an educator, Professor Luo is committed to excellence in teaching. He currently teaches undergraduate courses “University Physics C (Part 1)” and “University Physics C (Part 2)”, as well as the graduate course “Semiconductor Physics”. Under his mentorship, a team of first-year students won the first prize in the Beijing College Student Physics Academic Competition.

Education

Sep 2013 – July 2018	Ph.D. in Materials Science and Engineering Tsinghua University,   School of Materials Science and Engineering, Beijing, China
Apr 2016 – Oct 2016	Visiting scholar, Institute of Biointerfaces Materials Science and Engineering University of Michigan, USA
Sept 2009– Jun 2013	Bachelor in Materials Science and Engineering Rank No.1 in GPA score and No.1 in Comprehensive   evaluation score. China University of Geosciences (Beijing), China.

Work Experience

Nov 2021–present       Professor, College of Science, China Agricultural University

Sep 2018–Sep 2021     Research Associate, Department of Engineering

    University of Cambridge, UK

Research interests

Ø  Dielectric/ferroelectric/piezoelectric and other information functional ceramics and composites

Ø  Multi-scale structure regulation and multi-field coupling analysis of information functional materials

Ø  Prediction of Novel Information Functional Materials and Energy Storage and Conversion Applications

 

Publication

[1]   B. Luo et al., Proc Natl Acad Sci U S A 116, 17213 (2019).

[2]   B. Luo et al., Advanced Functional Materials 31, 2007994 (2020).

[3]   W. Feng, B. Luo, S. Bian, E. Tian, Z. Zhang, A. Kursumovic, J. L. MacManus-Driscoll, X. Wang, and L. Li, Nature Communications 13, 5086 (2022).

[4]   X. Yang et al., Advanced Functional Materials 32, 2200397 (2022).

[5]   B. Luo, L. Wu, D. Li, Z. Zhang, X. Yu, G. Li, and H. Song, Carbon 196, 146 (2022).

[6]   B. Luo, X. Wang, Q. Zhao, and L. Li, Composites Science and Technology 112, 1 (2015).

[7]   B. Luo, X. Wang, Y. Wang, and L. Li, J. Mater. Chem. A 2, 510 (2014).

[8]   B. Luo, X. Wang, E. Tian, H. Song, H. Wang, and L. Li, ACS Appl Mater Interfaces 9, 19963 (2017).

[9]   M. Hong et al., Journal of Materials Chemistry A 10, 18000 (2022).

[10] B. Luo, Y. Yao, E. Tian, K. Shen, H. Song, H. Song, and B. Li, J Phys Chem Lett 10, 5609 (2019).

[11] B. Luo, X. Wang, E. Tian, G. Li, and L. Li, Journal of Materials Chemistry C 3, 8625 (2015).

[12] B. Luo, X. Wang, E. Tian, H. Gong, Q. Zhao, Z. Shen, Y. Xu, X. Xiao, and L. Li, ACS Appl Mater Interfaces 8, 3340 (2016).

[13] B. Luo, X. Wang, H. Sun, and L. Li, Applied Physics Letters 108, 243901 (2016).

[14] Z. Zhang, B. Luo, X. Wang, X. Deng, K. Shen, and E. Tian, Surfaces and Interfaces 23, 100913 (2021).

[15] B. Luo et al., Materials Today Energy 12, 136 (2019).

[16] L. Wu, B. Luo, and E. Tian, Journal of Alloys and Compounds 866, 158933 (2021).

[17] B. Luo, X. Wu, and G. Li, International Journal of Modern Physics B 28 (2014).

[18] B. Luo, X. Wang, H. Wang, Z. Cai, and L. Li, Composites Science and Technology 151, 94 (2017).

[19] B. Luo, X. Wang, M. Tian, Z. Cai, and L. Li, Polymer Composites 40, 1000 (2019).

[20] B. Luo, X. Wang, E. Tian, L. Wu, and L. Li, Journal of Applied Physics 120, 074106 (2016).

[21] B. Luo, X. Wang, E. Tian, H. Song, Q. Zhao, Z. Cai, W. Feng, and L. Li, J. Eur. Ceram. Soc. (Netherlands) 38, 1562 (2018).

[22] B. Luo, X. Wang, E. Tian, H. Song, and L. Li, Ceramics International 43, 12988 (2017).

[23] B. Luo, X. Wang, E. Tian, H. Song, G. Li, and L. Li, Journal of Alloys and Compounds 708, 187 (2017).

[24] B. Luo et al., Journal of the American Ceramic Society 101, 2976 (2018).

[25] B. Luo, X. Wang, E. Tian, G. Li, and L. Li, Applied Surface Science 351, 558 (2015).

[26] Y. Yao, E. Tian, B. Luo, Y. Niu, H. Song, H. Song, and B. Li, Journal of Solid State Chemistry 289, 121477 (2020).

[27] E. Tian, Y. Yao, B. Luo, Y. Niu, H. Song, B. Li, and H. Song, The Journal of Physical Chemistry C 124, 11124 (2020).

[28] J. Sun, B. Luo, and H. Li, Advanced Energy and Sustainability Research 3, 2100191 (2022).

[29] B. Luo, L. Wu, Z. Zhang, G. Li, and E. Tian, iScience 25 (2022).

[30] B. Luo, X. Wang, E. Tian, H. Song, H. Qu, Z. Cai, B. Li, and L. Li, Ceramics International 44, 9684 (2018).

[31] Z. Lei et al., Journal of Materials Research and Technology 23, 1013 (2023).

[32] S. Jiang, B. Luo, K. Li, Y. Yin, Z. Zhang, T. Zhu, and X. Li, Journal of Cleaner Production 397, 136621 (2023).

[33] X. Deng, B. Luo, Z. Zhang, C. Zhao, M. Shi, and E. Tian, Physica E: Low-dimensional Systems and Nanostructures 130, 114690 (2021).

[34] X. Deng, B. Luo, Z. Zhang, Y. Yao, C. Zhao, M. Shi, and E. Tian, Physica B: Condensed Matter 603, 412703 (2021).

[35] S. Jiang, X. Li, Y. Yin, B. Luo, A. G. Isah, Z. Zhang, and T. Zhu, Journal of Hazardous Materials 441, 129894 (2023).

[36] X. Zeng, H. Zhang, X. Xi, B. Luo, P. Zhu, G. Li, B. Li, and J. Zhou, Ceramics International 48, 16273 (2022).

[37] X. Zeng, F. Zhang, X. Xi, H. Zhang, B. Luo, P. Zhu, G. Li, B. Li, and J. Zhou, Ceramics International 48, 27615 (2022).

[38] W. Yu et al., Journal of Cleaner Production 361, 132261 (2022).

[39] J. L. Liu, J. X. Xiao, B. C. Luo, E. K. Tian, and G. I. N. Waterhouse, Chemical Engineering Journal 427, 132038 (2022).

[40] C. Zhu et al., ACS Applied Materials & Interfaces 13, 28484 (2021).

[41] X. X. Zeng, B. C. Luo, H. Zhang, X. Q. Xi, B. Li, and J. Zhou, Ceramics International 47, 17662 (2021).

[42] J. L. Liu, J. X. Xiao, Z. Y. Wang, H. M. Yuan, Z. G. Lu, B. C. Luo, E. K. Tian, and G. I. N. Waterhouse, Acs Catalysis 11, 5386 (2021).

[43] Z. M. Cai, C. Q. Zhu, L. W. Wu, B. C. Luo, P. Z. Feng, and X. H. Wang, Applied Physics Letters 119, 032901 (2021).

[44] C. Q. Zhu, Z. M. Cai, B. C. Luo, L. M. Guo, L. T. Li, and X. H. Wang, Journal of Materials Chemistry A 8, 683 (2020).

[45] H. M. Qu, B. C. Luo, S. S. Bian, and Z. X. Yue, Materials Research Express 7, 046305 (2020).

[46] W. Feng, Z. Y. Cen, S. Y. Liang, B. C. Luo, Y. Zhang, Y. C. Zhen, X. H. Wang, and L. T. Li, Journal of Alloys and Compounds 786, 498 (2019).

[47] Z. M. Cai, X. H. Wang, B. C. Luo, P. Y. Zhao, C. Q. Zhu, and L. T. Li, Composites Science and Technology 173, 61 (2019).

[48] Z. M. Cai, X. H. Wang, Z. Y. Cen, B. C. Luo, and L. T. Li, Ceramics International 45, 8940 (2019).

[49] Q. C. Zhao, X. H. Wang, H. L. Gong, B. B. Liu, B. C. Luo, and L. T. Li, Journal of the American Ceramic Society 101, 1245 (2018).

[50] H. Liu et al., Electrochimica Acta 291, 31 (2018).

[51] L. Guo, Z. Yang, K. Marcus, Z. Li, B. Luo, L. Zhou, X. Wang, Y. Du, and Y. Yang, Energy & Environmental Science 11, 106 (2018).

[52] W. Feng, X. H. Wang, Z. Y. Cen, B. C. Luo, Q. C. Zhao, Z. B. Shen, and L. T. Li, Journal of Alloys and Compounds 744, 535 (2018).

[53] Z. M. Cai, X. H. Wang, B. C. Luo, and L. T. Li, Ceramics International 44, 843 (2018).

[54] Z. M. Cai, X. H. Wang, B. C. Luo, W. Hong, L. W. Wu, and L. T. Li, Journal of the American Ceramic Society 101, 1607 (2018).

[55] Z. M. Cai, X. H. Wang, W. Hong, B. C. Luo, Q. C. Zhao, and L. T. Li, Journal of the American Ceramic Society 101, 5487 (2018).

[56] C. Zhou, Q. Zhang, S. Liu, B. Luo, E. Yi, E. Tian, G. Li, L. Li, and G. Wu, Phys Chem Chem Phys 19, 11778 (2017).

[57] L. Wu, X. Wang, Z. Shen, B. Luo, and L. Li, Journal of the American Ceramic Society 100, 511 (2017).

[58] Z. M. Cai, X. H. Wang, B. C. Luo, L. W. Wu, and L. T. Li, Ceramics International 43, 12882 (2017).

[59] Z. M. Cai, X. H. Wang, B. C. Luo, W. Hong, L. W. Wu, and L. T. Li, Composites Science and Technology 145, 105 (2017).

[60] Z. M. Cai, X. H. Wang, B. C. Luo, W. Hong, L. W. Wu, and L. T. Li, Composites Science and Technology 151, 109 (2017).

[61] Q. C. Zhao, H. L. Gong, X. H. Wang, B. C. Luo, and L. T. Li, Physica Status Solidi a-Applications and Materials Science 213, 1077 (2016).

[62] Z. B. Shen, X. H. Wang, B. C. Luo, and L. T. Li, Journal of Materials Chemistry A 3, 18146 (2015).

[63] F. Z. Lv, R. Z. Zhang, L. A. Xu, B. C. Luo, and Y. H. Zhang, Journal of Sol-Gel Science and Technology 69, 26 (2014).

[64] X. W. Wu, M. H. Fang, L. F. Mei, and B. C. Luo, Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing 558, 446 (2012).

[65] X. W. Wu, Y. G. Liu, M. H. Fang, L. F. Mei, and B. C. Luo, Carbon 49, 1782 (2011).

https://scholar.google.co.uk/citations?hl=en&user=GJnLVcIAAAA

https://www.researchgate.net/profile/Bingcheng-Luo 

(1) Application of Advanced Functional Materials in the Field of Agricultural Resources and Environment

(2) Information functional ceramics and composites: dielectrics, ferroelectrics, piezoelectrics, multilayer ceramic capacitors, dielectric polymer composites

(3) Flexible electronic materials and energy storage devices: graphene-based 2D materials and devices, flexible supercapacitors, microcapacitors;

(4) High-throughput multi-scale design and theoretical prediction of new smart materials and structures.

(High-throughput calculations, first-principles, molecular dynamics, phase field simulations and finite element analysis)

Associate Editorial Board Member of Modern Agriculture (MODA)

Junior Editorial Board Member of Microstructure

Junior Editorial Board Member of Journal of Applied Optics

 

Senior Member of Chinese Materials Research Society (C-MRS)

Senior Member of the Chinese Institute of Electronics (CIE)

Senior Member of Chinese Society of Micro-Nano Technology (CSMNT)

Member of Chinese Physical Society (CPS)

Member of the Chinese Ceramic Society (CCS)

Member of Chinese Society of Plant Nutrition and Fertilizer Science (CSPNF)

 

He has served as a reviewer for many prestigious journals such as Nature Comm, Carbon, Journal of Physical Chemistry, Journal of Power Sources, Journal of Advanced Ceramics, iScience, and Composites Science and Technology.

Ø  Dielectric/ferroelectric/piezoelectric and other information functional ceramics and composites

Ø  Multi-scale structure regulation and multi-field coupling analysis of information functional materials

Ø  Prediction of Novel Information Functional Materials and Energy Storage and Conversion Applications

Undergraduate courses: course data for the last ten years
 1, College Physics C (Part II), 2022-2023, Second Semester, Tuesdays Fridays, East Campus
 2, College Physics C (Part II), 2022-2023, Second Semester, Tuesday Friday, East Campus
 3. College Physics C (Part II), 2022-2023, Second Semester, Tue Wed Fri, East Campus
 4, College Physics C (Part I), 2022-2023, First Semester, Tuesday, East Campus
 5, College Physics C (Part I), 2022-2023, First Semester, Friday, East Campus
 6. College Physics C (Part II), 2021-2022, Second Semester, Tuesday Friday, East Campus

[1]          Luo B, Yao Y, Tian E, Song H, Wang X, Li G, Xi K, Li B, Song H, Li L. Graphene-like monolayer monoxides and monochlorides. Proc Natl Acad Sci U S A2019, 116(35): 17213-17218.

[2]          Luo B, Shen Z, Cai Z, Tian E, Yao Y, Li B, Kursumovic A, MacManus‐Driscoll JL, Li L, Chen LQ, Wang X. Superhierarchical Inorganic/Organic Nanocomposites Exhibiting Simultaneous Ultrahigh Dielectric Energy Density and High Efficiency. Advanced Functional Materials2020, 31(8): 2007994.

[3]          Feng W, Luo B, Bian S, Tian E, Zhang Z, Kursumovic A, MacManus-Driscoll JL, Wang X, Li L. Heterostrain-enabled ultrahigh electrostrain in lead-free piezoelectric. Nature Communications2022, 13(1): 5086.

[4]          Yang X, Zheng X, Li H, Luo B, He Y, Yao Y, Zhou H, Yan Z, Kuang Y, Huang Z. Non‐Noble‐Metal Catalyst and Zn/Graphene Film for Low‐Cost and Ultra‐Long‐Durability Solid‐State Zn‐Air Batteries in Harsh Electrolytes. Advanced Functional Materials2022, 32(31): 2200397.

[5]          Luo B, Wu L, Li D, Zhang Z, Yu X, Li G, Song H. Novel atomic-scale graphene metamaterials with broadband electromagnetic wave absorption and ultra-high elastic modulus. Carbon2022, 196: 146-153.

[6]          Luo B, Wang X, Zhao Q, Li L. Synthesis, characterization and dielectric properties of surface functionalized ferroelectric ceramic/epoxy resin composites with high dielectric permittivity. Composites Science and Technology2015, 112: 1-7.

[7]          Luo B, Wang X, Wang Y, Li L. Fabrication, characterization, properties and theoretical analysis of ceramic/PVDF composite flexible films with high dielectric constant and low dielectric loss. J Mater Chem A2014, 2(2): 510-519.

[8]          Luo B, Wang X, Tian E, Song H, Wang H, Li L. Enhanced Energy-Storage Density and High Efficiency of Lead-Free CaTiO₃-BiScO₃ Linear Dielectric Ceramics. ACS Appl Mater Interfaces2017, 9(23): 19963-19972.

[9]          Hong M, Luo B, Zhou C, Xu S, Zhang L, Zhang Z, Yang Z, Hu N, Zhang Y, Liang Z. NiCoP nanoparticle-decorated carbon nanosheet arrays assembled on nickel nanowires for volumetric energy-dense supercapacitors. Journal of Materials Chemistry A2022, 10(35): 18000-18013.

[10]        Luo B, Yao Y, Tian E, Shen K, Song H, Song H, Li B. Interfacial Bonding and Electronic Structure between Copper Thiocyanate and Hybrid Organohalide Lead Perovskites for Photovoltaic Application. J Phys Chem Lett2019, 10(18): 5609-5616.

[11]        Luo B, Wang X, Tian E, Li G, Li L. Electronic structure, optical and dielectric properties of BaTiO₃/CaTiO₃/SrTiO₃ ferroelectric superlattices from first-principles calculations. Journal of Materials Chemistry C2015, 3(33): 8625-8633.

[12]        Luo B, Wang X, Tian E, Gong H, Zhao Q, Shen Z, Xu Y, Xiao X, Li L. Dielectric Enhancement in Graphene/Barium Titanate Nanocomposites. ACS Appl Mater Interfaces2016, 8(5): 3340-3348.

[13]        Luo B, Wang X, Sun H, Li L. Dielectric, ferroelectric, and thermodynamic properties of silicone oil modified PVDF films for energy storage application. Applied Physics Letters2016, 108(24).

[14]        Zhang Z, Luo B, Wang X, Deng X, Shen K, Tian E. Electronic structure and optical properties of SnO2/HC(NH2)2PbI3 interfaces from first-principles calculations. Surfaces and Interfaces2021, 23: 100913.

[15]        Luo B, Wang X, Tian E, Yao Y, Cai Z, Xi K, Song H, Song H, Li B, Li L. Interfacial electronic properties of ferroelectric nanocomposites for energy storage application. Materials Today Energy2019, 12: 136-145.

[16]        Wu L, Luo B, Tian E. Ferroelectric properties of BaTiO₃-BiScO₃ weakly coupled relaxor energy-storage ceramics from first-principles calculations. Journal of Alloys and Compounds2021, 866: 158933.

[17]        Luo B, Wu X, Li G. Electronic structure, elastic and thermal properties of semiconductor GaX (X = N, P, As, Sb) with zinc blende from first-principles calculation. International Journal of Modern Physics B2014, 28(27).

[18]        Luo B, Wang X, Wang H, Cai Z, Li L. P(VDF-HFP)/PMMA flexible composite films with enhanced energy storage density and efficiency. Composites Science and Technology2017, 151: 94-103.

[19]        Luo B, Wang X, Tian M, Cai Z, Li L. Homogeneity quantification of nanoparticles dispersion in composite materials. Polymer Composites2019, 40(3): 1000-1005.

[20]        Luo B, Wang X, Tian E, Wu L, Li L. First-principles effective Hamiltonian simulation of ABO₃-type perovskite ferroelectrics for energy storage application. Journal of Applied Physics2016, 120(7).

[21]        Luo B, Wang X, Tian E, Song H, Zhao Q, Cai Z, Feng W, Li L. Giant permittivity and low dielectric loss of Fe doped BaTiO₃ ceramics: Experimental and first-principles calculations. J Eur Ceram Soc (Netherlands)2018, 38(4): 1562-1568.

[22]        Luo B, Wang X, Tian E, Song H, Li L. Interfacial electronic and structural properties of SiO2(010)/BaTiO3(001) from first-principles calculations. Ceramics International2017, 43(15): 12988-12991.

[23]        Luo B, Wang X, Tian E, Song H, Li G, Li L. Electronic, dielectric and optical properties of orthorhombic lanthanum gallate perovskite. Journal of Alloys and Compounds2017, 708: 187-193.

[24]        Luo B, Wang X, Tian E, Qu H, Zhao Q, Cai Z, Wang H, Feng W, Li B, Li L. Chemical composition and temperature dependence of the energy storage properties of Ba_1-xSr_xTiO₃ ferroelectrics. Journal of the American Ceramic Society2018, 101(7): 2976-2986.

[25]        Luo B, Wang X, Tian E, Li G, Li L. Structural and electronic properties of cubic KNbO3 (001) surfaces: A first-principles study. Applied Surface Science2015, 351: 558-564.

[26]        Luo B, Wu L, Zhang Z, Li G, Tian E. A triatomic carbon and derived pentacarbides with superstrong mechanical properties. iScience2022, 25(8).

[27]        Luo B, Wang X, Tian E, Song H, Qu H, Cai Z, Li B, Li L. Mechanism of ferroelectric properties of (BaCa)(ZrTi)O3 from first-principles calculations. Ceramics International2018, 44(8): 9684-9688.

[28]        Cai ZM, Wang XH, Luo BC, Hong W, Wu LW, Li LT. Nanocomposites with enhanced dielectric permittivity and breakdown strength by microstructure design of nanofillers. Composites Science and Technology2017, 151: 109-114.

[29]        Shen ZB, Wang XH, Luo BC, Li LT. BaTiO₃-BiYbO₃ perovskite materials for energy storage applications. Journal of Materials Chemistry A2015, 3(35): 18146-18153.

[30]        Guo L, Yang Z, Marcus K, Li Z, Luo B, Zhou L, Wang X, Du Y, Yang Y. MoS2/TiO2 heterostructures as nonmetal plasmonic photocatalysts for highly efficient hydrogen evolution. Energy & Environmental Science2018, 11(1): 106-114.

[31]        Wu XW, Liu YG, Fang MH, Mei LF, Luo BC. Preparation and characterization of carbon foams derived from aluminosilicate and phenolic resin. Carbon2011, 49(5): 1782-1786.

[32]        Zhu CQ, Cai ZM, Luo BC, Guo LM, Li LT, Wang XH. High temperature lead-free BNT-based ceramics with stable energy storage and dielectric properties. Journal of Materials Chemistry A2020, 8(2): 683-692.

[33]        Zhu C, Cai Z, Luo B, Cheng X, Guo L, Jiang Y, Cao X, Fu Z, Li L, Wang X. Multiphase Engineered BNT-Based Ceramics with Simultaneous High Polarization and Superior Breakdown Strength for Energy Storage Applications. ACS Applied Materials & Interfaces2021, 13(24): 28484-28492.

[34]        Feng W, Cen ZY, Liang SY, Luo BC, Zhang Y, Zhen YC, Wang XH, Li LT. Enhanced temperature stability of electric-field-induced strain in KNN-based ceramics. Journal of Alloys and Compounds2019, 786: 498-506.

[35]        Cai ZM, Wang XH, Luo BC, Zhao PY, Zhu CQ, Li LT. Laminated structure-induced high dielectric strength and energy storage density in dielectric composites. Composites Science and Technology2019, 173: 61-65.

[36]        Zhao QC, Wang XH, Gong HL, Liu BB, Luo BC, Li LT. The properties of Al₂O₃ coated fine-grain temperature stable BaTiO₃-based ceramics sintered in reducing atmosphere. Journal of the American Ceramic Society2018, 101(3): 1245-1254.

[37]        Liu H, Gu W, Luo B, Fan P, Liao L, Tian E, Niu Y, Fu J, Wang Z, Wu Y, Lv G, Mei L. Influence of Fe doping on the crystal structure, electronic structure and supercapacitance performance of birnessite [(Na, K)x(Mn4+, Mn3+)2O4·1.5H2O] with high areal mass loading. Electrochimica Acta2018, 291: 31-40.

[38]        Feng W, Wang XH, Cen ZY, Luo BC, Zhao QC, Shen ZB, Li LT. Enhancement of strain by electrically-induced phase transitions in BNKT-based ceramics. Journal of Alloys and Compounds2018, 744: 535-543.

[39]        Cai ZM, Wang XH, Luo BC, Li LT. Hierarchical-structured dielectric permittivity and breakdown performances of polymer-ceramic nanocomposites. Ceramics International2018, 44(1): 843-848.

[40]        Cai ZM, Wang XH, Luo BC, Hong W, Wu LW, Li LT. Multiscale design of high-voltage multilayer energy-storage ceramic capacitors. Journal of the American Ceramic Society2018, 101(4): 1607-1615.

[41]        Cai ZM, Wang XH, Hong W, Luo BC, Zhao QC, Li LT. Grain-size-dependent dielectric properties in nanograin ferroelectrics. Journal of the American Ceramic Society2018, 101(12): 5487-5496.

[42]        Zhou C, Zhang Q, Liu S, Luo B, Yi E, Tian E, Li G, Li L, Wu G. Thermal mismatch strain induced disorder of Y2Mo3O12 and its effect on thermal expansion of Y2Mo3O12/Al composites. Phys Chem Chem Phys2017, 19(19): 11778-11785.

[43]        Wu L, Wang X, Shen Z, Luo B, Li L. Re-entrant relaxor behavior in BaTiO3-Bi(Zn2/3Nb1/3)O3ceramics. Journal of the American Ceramic Society2017, 100(2): 511-514.

[44]        Cai ZM, Wang XH, Luo BC, Wu LW, Li LT. Thermal-mechanical-electrical coupled design of multilayer energy storage ceramic capacitors. Ceramics International2017, 43(15): 12882-12887.

[45]        Cai ZM, Wang XH, Luo BC, Hong W, Wu LW, Li LT. Dielectric response and breakdown behavior of polymer-ceramic nanocomposites: The effect of nanoparticle distribution. Composites Science and Technology2017, 145: 105-113.

[46]        Zhao QC, Gong HL, Wang XH, Luo BC, Li LT. Influence of BaO-CaO-SiO2 on dielectric properties and reliability of BaTiO3-based ceramics. Physica Status Solidi a-Applications and Materials Science2016, 213(4): 1077-1081.

[47]        Lv FZ, Zhang RZ, Xu LA, Luo BC, Zhang YH. Composition and ionic change capacity variation of surfactant-intercalated MgFe-layered double hydroxides in the one step synthesis. Journal of Sol-Gel Science and Technology2014, 69(1): 26-32.

[48]        Wu XW, Fang MH, Mei LF, Luo BC. Effect of final pyrolysis temperature on the mechanical and thermal properties of carbon foams reinforced by aluminosilicate. Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing2012, 558: 446-450.

[49]        Tian E, Yao Y, Luo B, Niu Y, Song H, Li B, Song H. Tailoring the Dimension of Halide Perovskites Enables Quantum Wires with Enhanced Visible Light Absorption. The Journal of Physical Chemistry C2020, 124(20): 11124-11131.

[50]        Deng X, Luo B, Zhang Z, Zhao C, Shi M, Tian E. Structural, electronic, and optical properties of two-dimensional hafnium monoxide nanosheets. Physica E: Low-dimensional Systems and Nanostructures2021, 130: 114690.

[51]        Sun J, Luo B, Li H. A Review on the Conventional Capacitors, Supercapacitors, and Emerging Hybrid Ion Capacitors: Past, Present, and Future. Advanced Energy and Sustainability Research2022, 3(6): 2100191.

[52]        Lei Z, Duan S, Wu X, Gao C, Wang L, Min X, Huang Z, Fang M, Luo R, Luo B. High-performance electrothermal coatings based on natural flake graphite for multifunctional electrothermal applications. Journal of Materials Research and Technology2023, 23: 1013-1026.

[53]        Yao Y, Tian E, Luo B, Niu Y, Song H, Song H, Li B. Enhanced near-ultraviolet and visible light absorption of organic-inorganic halide perovskites by co-doping with cesium and barium: Insight from first-principles calculations. Journal of Solid State Chemistry2020, 289: 121477.

[54]        Deng X, Luo B, Zhang Z, Yao Y, Zhao C, Shi M, Tian E. Electronic, structural and optical properties of cerium and zinc co-doped organic-inorganic halide perovskites for photovoltaic application. Physica B: Condensed Matter2021, 603: 412703.

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The software works Patent

ü  Outstanding Contribution in Wiley Open Science Excellent Author Program

ü  Beijing Outstanding Graduates Award, 2018

ü  2^nd prize of outstanding PhD thesis in Tsinghua University , 2018

ü  Hongqi-Zhai Scholarship, Tsinghua University, 2017  

ü  National Scholarship (Graduate), Ministry of Education of P.R.China, 2016.  

ü  Outstanding Student Scholarship, Tsinghua University, 2015

ü  Shien-Kang Scholarship, Tsinghua University, 2014   

ü  Beijing Outstanding Graduates Award, 2013

ü  Outstanding Graduates Award, China University of Geoscience Beijing, 2013

ü  Excellent Top 10 Student Award, China University of Geoscience Beijing, 2012

ü  Beijing Merit Student Award, Beijing, 2012

ü  Merit Student Award, China University of Geoscience Beijing, 2012

ü  The First Prize Scholarship, Seven times, China University of Geoscience Beijing, 2010-2012

ü  National Scholarship (Undergraduate), Ministry of Education of P.R.China, 2011

ü  Model Student of Academic Records, China University of Geoscience, 2011

ü  The silver prize for 2^nd National Environmental Creative Competition, 2011

ü  Bronze Award for University Forum--Green Plastic, 2011

ü  National Scholarship (Undergraduate), Ministry of Education of P.R.China, 2010