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[I] 论文 第一/通讯作者 [44] Dual-sites Passivation for Efficient and Stable Carbon-Based Perovskite Solar Cells, Carbon, 2023 [43] Efficient Carbon-based Perovskite Solar Cells Passivated by Alkylammonium Chloride, Solar RRL, 2023 [42] MXene-basedWearable Thermoelectric Respiration Sensor, Nano Energy, 2023 [41] Robustly enhanced Seebeck coefficient in MXene/organics/TiS2 misfit structure for flexible thermoelectrics, ACS Applied Materials & Interfaces, 2023 [40] Co-enhanced electromagnetic shielding and thermoelectric performance in Bi2Te3 coated carbon cloth, Carbon, 2023. [39] Thermoelectric performance of Cu8SiS6 with high electronic band degeneracy, ACS Applied Electronic Materials, 2023. [38] Recent advances in Bi2Te3 electrodeposition and its thermoelectric applicationsin small-scale power generation and cooling, International Materials Reviews, 2022. DOI: 10.1080/09506608.2022.2145359. [37] Modifying carbon fiber fabric for flexible thermoelectric energy conversion, Applied Surface Science, 2022, 610, 155479. [36] Boosting thermoelectric performance of BayCo4Sb12 by interlinking largeaspect-ratio silver nanowires at the triple junction of grain boundaries, Materials Today Energy, 2022, 26,101007. [35] Sandwiched Graphene/Bi2Te3/Graphene Thermoelectric Film with Exceptional Figureof Merit for Flexibility, Advanced Materials Interfaces, 2022, 2200555. [34] MXene nanosheet/organics superlattice for flexible thermoelectrics. ACS Applied Nano Materials, 2022. DOI: 10.1021/acsanm.2c03813 [33] Construction of an MXene/organic superlattice for flexible thermoelectricenergy conversion. ACS Applied Energy Materials, 2022 5, 11351–11361. [32] A Bi2Te3-Filled Nickel Foam Film with Exceptional Flexibility and Thermoelectric Performance, Nanomaterials, 2022, 12, 1693. [31] Enhanced thermoelectric properties of binary CoSb3 by embedding FeCl3-intercalated graphene nanosheets, Journal of the European Ceramic Society, 2021, 41, 6523-6530. [30] Flexible foil of hybrid TaS2/organic superlattice: fabrication and electrical properties, Small, 2020, 1901901. [29] Graphene-Based Thermoelectrics, ACS Applied Energy Materials, 2020, 3,2224–2239. [28] Fabrication and characterization of hybrid Bi2Se3/organic superlattice forthermoelectric energy conversion, Advanced Electronic Materials, 2019, 1800842. [27] A P-type thermoelectric material BaCu4S3 with high electronic band degeneracy, Journal of Applied Physics, 2019, 126, 025102. [26] Converting natural diatomite into nanoporous silicon for eco-friendlythermoelectric energy conversion, Materials & Design, 2018, 154, 246–253. [25] Preparation and mechanical properties of Ce0.85Fe3CoSb12/rGO thermoelectricnanocomposite, Journal of Inorganic Material, 2017, 32, 33–38. [24] Skutterudite with graphene-modified grain-boundary complexion enhances zT enabling high-efficiency thermoelectric device, Energy & Environmental Science, 2017, 10, 183–191. [23] Construction of a 3D-rGO network-wrapping architecture in a YbyCo4Sb12/rGOcomposite for enhancing the thermoelectric performance, Journal of Materials Chemistry A, 2015, 3, 8643–8649. 合作作者: [22] Cu2ZnGeS4 as a novel hole transport material for carbon-based perovskite solarcells with power conversion efficiency above 18%, Chemical Engineering Journal,2023, 454, 140146. [21] High thermoelectric properties of shear-exfoliation-derived TiS2-AgSnSe2 nano-composites via ionized impurity scattering, Acta Materialia, 2023 244,118564 [20] A modified two-step sequential spin-coating method for perovskite solar cellsusing CsI containing organic salts in mixed ethanol/methanol solvent, Solar Energy Materials and Solar Cells, 2023, 250, 112107. [19] Cellular structured Cu2Sn0.8Co0.2S3 with enhanced thermoelectric performance realized by liquid-phase sintering, Journal of Materials Chemistry A, 2023, 11,1447–1454. [18] Low Temperature Processed SnO2 Electron Transporting Layer from Tin Oxalate for Perovskite Solar Cells, ACS Applied Energy Materials, 2022, 5, 15385–15391. [17] In-situ synthesis of gadolinium niobate quasi-binary composites with balanced mechanical and thermal properties for thermal barrier coatings, Journal ofAdvanced Ceramics, 2022, 11, 1445–1456. [16] Ultra-dense dislocations stabilized in high entropy oxide ceramics, Nature Communication, 2022, 13, 2871. [15] Effect of Heat Treatment on LaTi2Al9O19-Zr0.92Y0.08O1.96 Composite Coating Powders by Air Plasma Spraying, Rare Metal Materials and Engineering, 2022,51,1601–1605. [14] High thermoelectric performance of BiCuSeO via minimizing the electronegativity difference in Bi-O layer, Materials Today Physics, 2022, 24, 100688. [13] Enhancing thermoelectric performance of Bi2O2Se by W-doping with the shear exfoliation- restacking process, Materials Letters, 2022, 308, 131291. [12] Thermoelectric properties of Bi2-xTixO2Se with the shear exfoliation-restacking process, Journal of Alloys and Compounds, 2022, 892, 162147. [11] Influence of SnSe on thermoelectric properties of TiS2-xSnSe composites vialiquid-assisted shear exfoliation, Journal of Alloys and Compounds, 2022, 910,164914. [10] Enhanced thermoelectric performance in polymorphic heavily Co-doped Cu2SnS3 through carrier compensation by Sb substitution, Science and Technology ofAdvanced Materials, 2021, 22, 361. [9] Remarkable thermoelectric property enhancement in Cu2SnS3–CuCo2S4 nanocomposites via 3D modulation doping, Journal of Materials Chemistry A, 2021, 2021,9, 16928–16935. [8] High thermoelectric performance of Co-doped Cu2SnS3-attapulgite nano-compositesachieved by synergetic manipulation of electrical and thermal transport properties, Journal of Alloys and Compounds, 2021, 161338 [7] Thermal and mechanical properties of ferroelastic RENbO4 (RE = Nd, Sm, Gd, Dy,Er, Yb) for thermal barrier coatings, Scripta Materialia, 2021, 180, 51–56. [6] Embedding two-dimensional graphene array in ceramic matrix, Science Advance,2020, 6, 39, eabb1338. [5] Thermoelectric properties of BiSbTe/graphene nanocomposites, Journal of Materials Science: Materials in Electronics, 2019, 30, 11923. [4] Effect of multiwall carbon nanotubes on the thermoelectric properties of BiSbTe based composites, Rare Metal Materials and Engineering, 2018, 47, 466–469. [3] Study on the Ballistic Performance of B4C/Al2O3 Composite Ceramic Prepared by Reaction Sintering, Journal of Inorganic Material, 2018, 33, 545. [2] The structure of filled skutterudites and the local vibration behavior of the filling atom, Physica B-Condensed Matter, 2017, 507, 131. [1] Ultrahigh thermoelectric power factor in flexible hybrid inorganic-organic superlattice, Nature Communication, 2017, 8, 1024.
[II] 专利 [16] 半导体制冷医疗头盔,实用新型专利,202322745628.1 [15] 导电聚合物和边缘氧化石墨烯热电复合材料,发明专利,202310476142.4 [14] 一种自支撑聚苯胺基薄膜及其制备方法,发明专利,2023101177116 [13] 常温区热电发电薄膜用浆料及浆料和薄膜的制备方法,发明专利,202211554945.9 [12] 钙钛矿前驱体溶液和钙钛矿太阳能电池及其制备方法,发明专利,202211546519.0 [11] 钙钛矿前驱体溶液和钙钛矿薄膜及其其制备方法,发明专利,202211665129.5 [10] 一种聚酰胺复合纳滤膜,发明专利,202210219716.5 [9] 泡沫金属/碲化铋热电复合材料,发明专利,202210052884.X. [8] 碲化铋基合金/碳布热电复合材料及其制备方法,发明专利,202210078322.2 [7] 复合热电材料及其制备方法,发明专利,ZL 201310722885.1 [6] 一种纳米晶多孔硅热电材料及其制备方法,发明专利,ZL201711381581.8 [5] 一种钡铜硫基热电材料及其制备方法,发明专利,ZL 201910398489.5 [4] 一种铜硅硫基热电材料及其制备方法,发明专利,ZL 201910399152.6 [3] 一种铜铟硫基热电材料及其制备方法,发明专利,ZL 201910575836.7 [2] 一种钾铜硫基热电材料及其制备方法,发明专利,ZL 201910574820.4 [1] 铜硫基热电化合物及其制备方法,发明专利,ZL 201910575801.3 [III] 著作 [1] 能源材料手册,第33章,水性电池,重庆大学出版社,2023年; [2] Flexible Electronic Packaging and Encapsulation Technology, Chapter 2, Basic Concepts Related to Flexible Electronic Packaging, Weily, 2023 |