第 4 期                      宁可心, 等: 含氢无定型碳摩擦转移膜结构演化规律研究                                       491

                c. a-C:H薄膜在N 环境中的低摩擦磨损是由对偶                     [10]  Sánchez-López  J  C,  Erdemir  A,  Donnet  C,  et  al.  Friction-induced
                               2
            球上含具有典型DLC特征的碳转移膜的稳定存在与                                structural  transformations  of  diamondlike  carbon  coatings  under
                          2
            滑动界面间富sp 结构的形成产生的“石墨化”现象共                              various  atmospheres[J].  Surface  and  Coatings  Technology,  2003,
                                                                   163-164: 444–450. doi: 10.1016/S0257-8972(02)00641-2.
            同保证的，二者具有协同作用.
                                                               [11]  Wang  Jingjing,  Shang  Lunlin,  Li  Xia,  et  al.  Quantifying
                综上所述，转移膜确实可以起到降低摩擦磨损的
                                                                   macroscopic  friction  of  diamond-like  carbon  films  by  microscopic
            作用，但在N 氛围中可以形成具有典型DLC特征的碳
                       2                                           adsorption  and  removal  of  water  molecules[J].  Langmuir,  2018,
            转移膜并在一定程度上保护其稳定存在，从而进一步                                34(1): 58–65. doi: 10.1021/acs.langmuir.7b02613.
            降低摩擦磨损. 该结果可为后期使用a-C:H薄膜作为                         [12]  Erdemir  A,  Bindal  C,  Pagan  J,  et  al.  Characterization  of  transfer
            固体润滑材料，通过调控碳转移膜从而控制滑动界面                                layers  on  steel  surfaces  sliding  against  diamond-like  hydrocarbon
                                                                   films  in  dry  nitrogen[J].  Surface  and  Coatings  Technology,  1995,
            间的摩擦提供思路.
                                                                   76-77(1-3): 559–563. doi: 10.1016/0257-8972(95)02518-9.
            参 考 文 献                                            [13]  Manimunda P, Al-Azizi A, Kim S H, et al. Shear-induced structural
                                                                   changes  and  origin  of  ultralow  friction  of  hydrogenated  diamond-
            [  1  ]  Robertson J. Hard amorphous (diamond-like) carbons[J]. Progress in
                                                                   like carbon (DLC) in dry environment[J]. ACS Applied Materials &
                 Solid  State  Chemistry,  1991,  21(4):  199–333.  doi:  10.1016/0079-
                                                                   Interfaces, 2017, 9(19): 16704–16714. doi: 10.1021/acsami.7b03360.
                 6786(91)90002-H.
            [  2  ]  Erdemir  A,  Donnet  C.  Tribology  of  diamond-like  carbon  films:  [14]  Liu Shuwei, Zhang Chenhui, Osman E, et al. Influence of tribofilm
                                                                   on superlubricity of highly-hydrogenated amorphous carbon films in
                 recent  progress  and  future  prospects[J].  Journal  of  Physics  D:
                                                                   inert  gaseous  environments[J].  Science  China  Technological
                 Applied  Physics,  2006,  39(18):  R311–R327.  doi:  10.1088/0022-
                                                                   Sciences, 2016, 59(12): 1795–1803. doi: 10.1007/s11431-016-0078-
                 3727/39/18/r01.
            [  3  ]  Igartua A, Berriozabal E, Nevshupa R, et al. Screening of diamond-  6.
                 like  carbon  coatings  in  search  of  a  prospective  solid  lubricant  [15]  Yong Qingsong, Wang Haidou, Xu Binshi, et al. Research status of
                 suitable  for  both  atmosphere  and  high  vacuum  applications[J].  the tribological property of diamond-like carbon films[J]. Journal of
                                                                   Mechanical Engineering, 2016, 52(11): 95–107 (in Chinese) [雍青
                 Tribology International, 2017, 114: 192–200. doi: 10.1016/j.triboint.
                 2017.04.024.                                      松, 王海斗, 徐滨士, 等. 类金刚石薄膜摩擦机理及其摩擦学性能
            [  4  ]  He Dongqing, Li Xia, Pu Jibin, et al. Improving the mechanical and  影响因素的研究现状[J]. 机械工程学报, 2016, 52(11): 95–107].
                 tribological  properties  of  TiB 2 /a-C  nanomultilayers  by  structural  doi: 10.3901/JME.2016.11.095.
                 optimization[J].  Ceramics  International,  2018,  44(3):  3356–3363.  [16]  Chen Lin, Wu Jian, Zhang Guangan, et al. Probing the tribological
                 doi: 10.1016/j.ceramint.2017.11.125.              properties of diamond-like carbon under methane by tailoring sliding
            [  5  ]  Wang Chengbing, Li Hongxuan, Xu Tao. Tribological property of  interface[J]. Tribology, 2020, 40(2): 150–157 (in Chinese) [陈琳, 吴
                 diamond-like carbon film at different humidity in air[J]. Tribology,  健, 张广安, 等. 界面调控对类金刚石碳基薄膜在甲烷气氛下摩擦
                 2005, 25(5): 426–430 (in Chinese) [王成兵, 李红轩, 徐洮. 相对湿  学性能的影响[J]. 摩擦学学报, 2020, 40(2): 150–157]. doi: 10.16078/
                 度对类金刚石薄膜摩擦磨损性能的影响[J]. 摩擦学学报, 2005,                j.tribology.2019163.
                 25(5): 426–430]. doi: 10.16078/j.tribology.2005.05.010.  [17]  Cui Longchen, Lu Zhibin, Wang Liping. Toward low friction in high
            [  6  ]  Erdemir A, Eryilmaz O. Achieving superlubricity in DLC films by  vacuum  for  hydrogenated  diamondlike  carbon  by  tailoring  sliding
                 controlling bulk, surface, and tribochemistry[J]. Friction, 2014, 2(2):  interface[J].  ACS  Applied  Materials  &  Interfaces,  2013,  5(13):
                 140–155. doi: 10.1007/s40544-014-0055-1.          5889–5893. doi: 10.1021/am401192u.
            [  7  ]  Ren Siming, Zheng Shaoxian, Pu Jibin, et al. Study of tribological  [18]  Li  Hongxuan,  Xu  Tao,  Hao  Junying,  et  al.  Effect  of  matching
                 mechanisms  of  carbon-based  coatings  in  antiwear  additive  materials on the tribological properties of amorphous hydrogenated
                 containing  lubricants  under  high  temperature[J].  RSC  Advances,  carbon film[J]. Tribology, 2004, 24(6): 483–487 (in Chinese) [李红
                 2015, 5(81): 66426–66437. doi: 10.1039/c5ra08879h.  轩, 徐洮, 郝俊英, 等. 摩擦偶件材料对非晶含氢碳薄膜摩擦学性
            [  8  ]  Wang  Shunhua,  Huo  Lei,  Ju  Pengfei,  et  al.  The  first-principles  能的影响[J]. 摩擦学学报, 2004, 24(6): 483–487]. doi: 10.16078/
                 calculations  of  the  interaction  of  H 2 O  and  O 2   molecules  on  the  j.tribology.2004.06.001.
                 surface of hydrogen-free diamond films[J]. Tribology, 2019, 39(3):  [19]  Wang  Xiongwei,  Chai  Liqiang,  Pang  Xianjuan,  et  al.  Influence  of
                 350–356 (in Chinese) [王顺花, 霍磊, 鞠鹏飞, 等. 无氢类金刚石薄    salt spray test to DLC film on tribological properties[J]. Tribology,
                 膜表面H 2 O和O 2 分子共同作用的第一性原理计算[J]. 摩擦学学              2018, 38(4): 453–461 (in Chinese) [王雄伟, 柴利强, 逄显娟, 等. 盐
                 报, 2019, 39(3): 350–356]. doi: 10.16078/j.tribology.2018013.  雾腐蚀对DLC薄膜摩擦学性能的影响[J]. 摩擦学学报, 2018,
            [  9  ]  Donnet C, Erdemir A. Tribology of diamond-like carbon films[M].  38(4): 453–461]. doi: 10.16078/j.tribology.2018.04.010.
                 Boston, MA: Springer US, 2008. doi: 10.1007/978-0-387-49891-1.  [20]  Scharf T W, Singer I L. Role of the transfer film on the friction and