学术论文
1. Chen C. K., Guo D. F., Fan D., Lu S. H., Jiang M. Y., Li X., Hu X. J. Semiconductive vertical graphene nanoribbons self-assembled on diamond (100) surface by oxidation: A DFT study[J]. Appl Surf Sci. 2022, 604:154646.
2. Chen C, Fan D, Xu H, Jiang M, Li X, Lu S, et al. Monoatomic tantalum induces ordinary-pressure phase transition from graphite to n-type diamond. Carbon. 2022;196:466-73.
3. Jiang, M.; Chen, C.(共一); Wang, P.; Guo, D.; Han, S.; Li, X.; Lu, S.; Hu, X. Diamond formation mechanism in chemical vapor deposition. Proceedings of the National Academy of Sciences 2022, 119 (16). DOI: 10.1073/pnas.2201451119
4. Chen C, He Z, Chen W-E, Yeh C-R, Lin C-R, Leou K-C, et al. Plasma Post-Treatment Process-Induced Grain Coalescence to Improve the Electron Field-Emission Properties of Ultrananocrystalline Diamond Films. Phys Status Solidi A-Appl Mat. 2022.
5. Chen C, Tang B, Xu H, Pan J, Jiang M, Li X, Hu X. Low-Defect Nanodiamonds and Graphene Nanoribbons Enhanced Electron Field Emission Properties in Ultrananocrystalline Diamond Films [J]. ACS Applied Electronic Materials, 2021, 3(4): 1648-55.
6. Chen, C., He, Z., Xu, A., Li, X., Jiang, M. et al. Design and optimization of diamond mid-infrared phase shifter. Functional Diamond, 1-11, doi:10.1080/26941112.2020.1869485 (2021).
7. Chen, C. K., Xu, A. C., Li, X., Jiang, M. Y., Xu, T. et al. Design and Performance of Diamond-Based Mid-Infrared Sensor. Phys. Status Solidi A-Appl. Mat. 217, 6, doi:10.1002/pssa.202000076 (2020).
8. Chen, C., Mei, Y., Cui, J., Li, X., Jiang, M. et al. Man-made synthesis of ultrafine photoluminescent nanodiamonds containing less than three silicon-vacancy colour centres. Carbon 139, 982-988, doi:10.1016/j.carbon.2018.08.013 (2018).
9. Sheng, L. X., Chen, C. K., Jiang, M. Y., Li, X. & Hu, X. J. Effects of microwave oxygen plasma treatments on microstructure and Ge-V photoluminescent properties of diamond particles*. Chinese Physics B 29, 6, doi:10.1088/1674-1056/ab8db0 (2020).
10. Fan, Dong; Chen, Chengke; Lu, Shaohua; Li, Xiao; Jiang, Meiyan; Hu, Xiaojun*; Highly Stable Two-Dimensional Iron Monocarbide with Planar Hypercoordinate Moiety and Superior Li-Ion Storage Performance, ACS Applied Materials & Interfaces, 2020, 12(27):30297-30303.
11. Lu, S., Fan, D., Chen, C., Mei, Y., Ma, Y. et al. Ground-state structure of oxidized diamond (100) surface: An electronically nearly surface-free reconstruction. Carbon 159, 9-15, doi:https://doi.org/10.1016/j.carbon.2019.12.003 (2020).
12. Fan Dong, Lu Shaohua, Chen Chengke, Jiang Meiyan, Li Xiao, Hu Xiaojun. Versatile two-dimensional boron monosulfide polymorphs with tunable bandgaps and superconducting properties. [J]Applied Physics Letters, 2020,117(1)
13. Jiang, M., Zhang, Z., Chen, C., Ma, W., Han, S. et al. High efficient oxygen reduced reaction electrodes by constructing vertical graphene sheets on separated papillary granules formed nanocrystalline diamond films. Carbon 168, 536-545, doi:10.1016/j.carbon.2020.06.031 (2020).
14. Jiang M Y, Ma W C, Han S J, Chen C. K, Fan D, Li X,Hu XJ*. Microstructure and electrochemical properties of nanocrystalline diamond and graphene hybridized films [J]. J. Appl. Phys., 2020, 127(1): 015301.
15. Xiao Li, ChengCheng Wang, Chengke Chen, Meiyan Jiang, XiaojunHu*. Thickness-controllable diamond films deposited on stainless steel using a Cr/Cr-Si-N interlayer prepared at different N2/Ar flow ratios[J].Applied Surface Science,2020,532,147402
16. Feng Lyu, Xiao Li, Chengke Chen, Cheng Liu, Chuanxing Li, Meiyan Jiang, Xiaojun Hu*,High adhesion diamond films deposited on stainless steel by using nanocomposite films with mosaic interface as an interlayer [J]. Applied Surface Science,528, 2020, 146916
17. Wang, J. L., Chen, C. K., Li, X., Jiang, M. Y. & Hu, X. J. Influences of grain size and microstructure on optical properties of microcrystalline diamond films. Chinese Physics B 29, 6, doi:10.1088/1674-1056/ab593d (2020).
18. Ke, C. C., Fan, D., Chen, C. K., Li, X., Jiang, M. Y. et al. Two-dimensional tetragonal transition-metal carbide anodes for non-lithium-ion batteries. PCCP 22, 13680-13688, doi:10.1039/d0cp00839g (2020).
19. D. Fan, A.A. Golov, A.A. Kabanov, C. Chen, S. Lu, X. Li, M. Jiang, X. Hu*, A New sp2-sp3-Hybridized Metallic Carbon Network for Lithium-ion Battery Anode with Enhanced Safety and Lithium-ion Diffusion Rate, J. Phys. Chem. C, 2019, 123, 15412−15418.
20. X Li, C Li, C Chen, C Liu, F Lyu, M Jiang, X. Hu*, Adherent and smooth diamond film deposited on stainless steel by using AlSiN interlayers, Applied Surface Science, 2019, 487, 464-472.
21. Hang-Cheng Zhang, Cheng-Ke Chen, Ying-Shuang Mei, Xiao Li, Mei-Yan Jiang, and Xiao-Jun Hu*, Micron-sized diamond particles containing Ge-V and Si-V color centers, Chinese Physics B, 2019, 28(7), 076103.
22. Fan D, Lu S, Chen C, Jiang M, Li X, Hu X*. A novel hydrogenated boron–carbon monolayer with high stability and promising carrier mobility[J]. Physical Chemistry Chemical Physics, 2019, 21, 2572-2577.
23. Mei Y, Chen C, Jiang M, et al. Photoluminescence of SiV centers in CVD diamond particles with specific crystallographic planes. [J]. Chinese Physics B, 2019, 28(016101.
24. Mei Y, Chen C, Fan D, et al. Enhanced SiV photoluminescence by oxidation induced nano-structures on diamond particle surface [J]. Nanoscale, 2018, 11(2):
25. Xu H, Chen C, Fan D, et al. Oxygen ion implanted grains dominantly contributed electron field emission of nanocrystalline diamond films [J]. Carbon, 2019, 145(187-94.
26. Yang Z, Mei Y, Chen C, et al. Synthesis of strong SiV photoluminescent diamond particles on silica optical fiber by chemical vapor deposition [J]. Chinese Physics B, 2018, 27(3): 038101.
27. Hu X, Chen C, Lu S. High mobility n-type conductive ultrananocrystalline diamond and graphene nanoribbon hybridized carbon films [J]. Carbon, 2016, 98(671-80.
28. Chen W-E, Chen C, Yeh C-J, et al. Evolution of Granular Structure and the Enhancement of Electron Field Emission Properties of Nanocrystalline and Ultrananocrystalline Diamond Films Due to Plasma Treatment Process [J]. ACS applied materials & interfaces, 2018, 10(34): 28726-35.
29. 陈成克, 胡晓君. 生长时间对纳米金刚石薄膜微结构的影响 [J]. 超硬材料工程, 2014, 26(3): 22-5.
30. 胡晓君, 刘建军, 徐辉, 陈成克. 纳米金刚石薄膜的掺杂与电学性能研究 [J]. 超硬材料工程, 2017, 6): 30-3.
31. 陈隆, 陈成克, 李晓, 胡晓君*. 氧化对单颗粒层纳米金刚石薄膜硅空位发光和微结构的影响[J]. 物理学报, 2019, 68(16): 168101-168101.
32. 蒋梅燕, 朱政杰, 陈成克, 李晓, 胡晓君*, 硫离子注入纳米金刚石薄膜的微结构和电化学性能, 物理学报, 2019, 68(14), 148101-148101.
授权专利:
1. 胡晓君,陈成克,一种高迁移率的n型纳米金刚石-石墨烯纳米带复合薄膜及制备方法,授权:ZL 2015 1 0219422.2,申请日:2015年4月30日授权时间:2017-09-26
2. 胡晓君,陈成克,一种纳米金刚石-石墨烯纳米带复合薄膜及其制备方法,授权:ZL 2015 1 0219725.4 申请号:201510219725.4申请日:2015年4月30日授权时间:2017-09-26
3. 胡晓君,陈成克,具有SiV 发光的超小晶粒尺寸纳米金刚石薄膜及其制备,ZL201610870721.7 授权时间:2019-06-14
4. 胡晓君; 陈成克;徐辉; 刘建军; 梅盈爽; 樊冬, 一种具有晶粒密堆积结构的高迁移率n型纳米金刚石薄膜及其制备方法, 2020-06-09至2040-06-09, 中国, ZL201810247215.1.
5. 胡晓君; 徐辉; 梅盈爽; 陈成克; 樊冬, 一种晶粒密堆积n型纳米金刚石薄膜及其制备方法, 2020-06-23至2040-06-23, 中国, ZL201810245815.4.
6. 胡晓君; 刘建军; 徐辉; 梅盈爽; 陈成克; 樊冬, 一种高迁移率n型超薄纳米金刚石薄膜及其制备方法, 2020-06-09至2040-06-09, 中国, ZL201810246649.X.
国际专利
1. Xiaojun Hu, Chengke Chen, Nanocrystalline diamond films with ultrafine grains and its preparation method, US 11,186,923 B2