教学研究成果
获奖情况:
教育部技术发明一等奖(排名2/6)
发明专利:
(1)裴延玲, 宫声凯, 吴琼, 李树索, 马岳. 一种Cr改性的高Mo的Ni3Al基单晶高温合金及其制备方法. 发明专利, 专利号ZL201110125242.X
(2)裴延玲, 郭洪波, 宫声凯. 一种氧化物陶瓷InFeZnO4热障涂层材料及其制备方法. 发明专利, 专利号ZL201110110375.X
(3)裴延玲, 宫声凯. 一种Sr掺杂氧化物BiCuSeO热电材料及制备方法.发明专利, 专利号ZL201210132429.7
(4)裴延玲, 尚勇, 吴萌萌, 张恒, 宫声凯. 一种模拟航空发动机高温服役环境的热力化耦合试验装置. 发明专利, 专利号ZL202110766353.2
(5)裴延玲, 茹毅, 李树索, 刘熠, 吴小雨, 邹宇凯, 常肖文, 宫声凯. 一种设计单晶高温合金固溶制度的方法. 发明专利, 专利号ZL201310289294.X
(6)裴延玲, 段浩东. 一种快速测定镍基单晶高温合金内应力的方法. 发明专利, 专利号ZL201910226815.4
(7)裴延玲, 宫声凯, 林杰, 李树索, 胡斌. 一种籽晶法单晶生长取向精确控制模壳及其制造方法. 发明专利, 专利号ZL201810562755.9
(8)裴延玲, 胡斌, 李树索, 宫声凯. 一种基于二次取向控制的单晶高温合金薄壁铸件及其制备方法. 发明专利, 专利号ZL202010222079.8
(9)裴延玲, 胡晓甫, 刘巧沐, 李树索, 陈小雨, 宫声凯. 一种磁性金属@SiC吸波粉末及其制备方法. 发明专利, 专利号ZL202211308169.4
(10)裴延玲, 梁凯铭, 毕晓昉, 李树索, 宫声凯, 伊万卓罗斯•赫里斯道法奥柔. 一种原位应力检测修复集成系统. 发明专利, 专利号ZL201911178347.4
代表性论文:
[1]Pei Yan-Ling*, Wu Haijun, Wu Di, Zheng Fengshan, He Jiaqing*. High Thermoelectric Performance Realized in a BiCuSeO System by Improving Carrier Mobility through 3D Modulation Doping. Journal of the American Chemical Society, 2014, 136(39): 13902-13908.
[2]Pei Yanling, Chang Cheng, Wang Zhe, Yin Meijie, Wu Minghui, Tan Gangjian, Wu Haijun, Chen Yuexing, Zheng Lei, Gong Shengkai, Zhu Tiejun, Zhao Xinbing, Huang Li, He Jiaqing, Kanatzidis Mercouri G.*, Zhao LiDong*. Multiple Converged Conduction Bands in K2Bi8Se13: A Promising Thermoelectric Material with Extremely Low Thermal Conductivity. Journal of the American Chemical Society, 2016, 138(50): 16364-16371.
[3]Pei Yanling1, Wu Haijun1, Sui Jiehe1, Li Jing, Berardan David, Barreteau Celine, Pan Lin, Dragoe Nita, Liu Weishu, He Jiaqing*, Zhao Lidong*. High thermoelectric performance in n-type BiAgSeS due to intrinsically low thermal conductivity. Energy & Environmental Science, 2013, 6(6): 1750-1755.
[4]Pei Yanling, Tan Gangjian, Feng Dan, Zheng Lei, Tan Qing, Xie Xiaobing, Gong Shengkai, Chen Yue, Li Jing-Feng, He Jiaqing, Kanatzidis Mercouri G.*, Zhao Li-Dong*. Integrating Band Structure Engineering with All-Scale Hierarchical Structuring for High Thermoelectric Performance in PbTe System. Advanced Energy Materials, 2017, 7(3): 16014503.
[5]Liu Zihang1, Pei Yanling1, Geng Huiyuan, Zhou Jingchao, Meng Xianfu, Cai Wei, Liu Weishu*, Sui Jiehe*. Enhanced thermoelectric performance of Bi2S3 by synergistical action of bromine substitution and copper nanoparticles. Nano Energy, 2015, 13:554-562.
[6]Zhao Li-Dong, Pei Yan-Ling*, Liu Yong, Berardan David, Dragoe Nita. InFeZnO4 as Promising Thermal Barrier Coatings. Journal of the American Ceramic Society, 2011, 94(6): 1664-1666.
[7]Zhou Y. M.1, Wu H. J.1, Pei Y. L.*, Chang C., Xiao Y., Zhang X., Gong S. K., He J. Q., Zhao L.-D.*. Strategy to optimize the overall thermoelectric properties of SnTe via compositing with its property-counter CuInTe2. Acta Materialia, 2017, 125: 542-549.
[8]Qu Weiwei, Li Shusuo, Chen Zehao, Li Chun, Pei Yanling*, Gong Shengkai. Hot corrosion behavior and wettability of calcium-magnesium-alumina-silicate (CMAS) on LaTi2Al9O19 ceramic. Corrosion Science, 2020, 162(108199).
[9]Qu Weiwei, Chen Zehao, Li Shusuo, Wu Mengmeng, Pei Yanling*, Gong Shengkai. Failure mechanism of YSZ coatings prepared by EB-PVD under partial penetration of CMAS attacking. Corrosion Science, 2022, 203(110339).
[10]Ma Zhe, Pei Yan-Ling*, Luo Liang, Qin Lu, Li Shusuo, Gong Shengkai. Partitioning behavior and lattice misfit of γ/γ′ phases in Ni-based superalloys with different Mo additions. Rare Metals, 2020, 40(4): 920-927.