[1] 第一作者. deeply nesting zinc sulfide dendrites in tertiary hierarchical structure for potassium ion batteries: enhanced conductivity from interior to exterior. acs nano 2019, 13, 6906-6916. (if=17.1,top期刊) [2] 第一作者. schottky junction and multiheterostructure synergistically enhance rate performance and cycling stability, chemical engineering journal, 430 (2022) 132994. (if=15.1,top期刊) [3] 第一作者. open znse/c nanocages: multi-hierarchy stress buffer for boosting cycling stability in potassium ion batteries. journal of materials chemistry a, 2020, 8, 779-788. (if=11.9,top期刊) [4] 第一作者. yolk–shell structured fes/mos2@nitrogen-doped carbon nanocubes with sufficient internal void space as an ultrastable anode for potassium-ion batteries. journal of materials chemistry a, 2020, 8, 23983-23993. (if=11.9,top期刊) [5] 第一作者. short-range graphitic nanodomains in hypocrystalline carbon nanotubes realize fast potassium ion migration and multidirection stress release. small 2023, 2304406. (if=13.3,top期刊) [6] 第一作者. a novel graphene-wrapped corals-like nise2 for ultrahigh-capacity potassium ion storage. carbon 2020, 161, 834-841. (if=10.9,top期刊) [7] 第一作者. kinetic study of mn vacuum evaporation from mn steel melts. separation and purification technology 2021, 255, 117698. (if=8.6,top期刊) [8] 第一作者. thickness-control of ultrathin bimetallic fe-mo selenide @n-doped carbon core/shell “nano-crisps” for high-performance potassium-ion batteries. applied materials today 2018, 13, 344-351. (if=8.3) [9] 通讯作者. design and optimization of carbon materials as anodes for advanced potassium-ion storage. rare metals 2024. (if=8.8) [10] 第一作者. corrosion behaviour of mgo-based refractories by different existence states of manganese-containing volatile phases. journal of the european ceramic society 2023, 43, 3755-3769. (if=5.7,top期刊) [11] 第一作者. formation, evolution and remove behavior of manganese-containing inclusions in medium/high manganese steels. journal of materials research and technology 2023, 22, 1505-1521. (if=6.4,top期刊) [12] 第一作者. characterization of precipitation, evolution, and growth of mns inclusions in medium/high manganese steel during solidification process. materials characterization 2022, 112367. (if=4.7) [13] 第一作者. characterization of oxidation behavior of mn fumes generated in the vacuum treatment of melting mn steels. steel research international 2021, 92, 2000333. (if=2.2) [14] 第一作者. study on the relationship between vacuum denitrification and manganese evaporation behaviours of manganese steel melts, vacuum 2021, 192: 110420. (if=4.0) [15] 第一作者. mn evaporation and denitrification behaviors of molten mn steel in the vacuum refining with slag process. international journal of minerals metallurgy and materials 2021, 28(8): 1288-1297. (if=4.8) [16] 第一作者. volatilization behavior of manganese from molten steel with different alloying methods in vacuum. metals 2020, 10, 1348. (if=2.9) [17] 通讯作者. the effect of alloying elements on formation and evolution mechanism of manganese-containing inclusions in medium/high-manganese steels. steel research international 2023, 2300653. (if=2.2) |
