纳米MoS_2的制备及其在润滑油添加剂中的研究现状

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英文篇名：Preparation and Progress of Molybdenum Disulfide as Lubricatant Additives 作者：伍友清 ; 常峰 ; 韩春梅 ; 余昊 ; 张磊 ; 周太刚 ; 唐庆 ; 何毅 英文作者：WU Youqing;CHANG Feng;HAN Chunmei;YU Hao;ZHANG Lei;ZHOU Taigang;TANG Qing;HE Yi;College of Chemistry and Chemical Engineering,Southwest Petroleum University;Oil Production Engineering of Shengli Oilfield,China Petroleum & Chemical Corporation;China Petroleum Southwest Lubricating Oil Branch;Oil Production Technology Research Institute of CNPC; 关键词：纳米二硫化钼 ; 润滑油添加剂 ; 表面修饰 英文关键词：MoS2;;lubricant additive;;surface modification 中文刊名：CLDB 英文刊名：Materials Review 机构：西南石油大学化学化工学院;中国石化股份胜利油田分公司采油工程处;中国石油西南润滑油分公司;中石油大港油田采油工艺研究院; 出版日期：2018-11-25 出版单位：材料导报 年：2018 期：v.32 语种：中文; 页：CLDB2018S2080 页数：5 CN：S2 ISSN：50-1078/TB 分类号：354-358

摘要

纳米二硫化钼(MoS_2)是典型的类石墨烯二维材料,具有出色的电学、光学、热学和力学性能,是当前研究的热点之一。本综述详细介绍了二维碳纳米材料-二硫化钼的纳米摩擦学性能,以及作为润滑油添加剂的研究进展,总结了二硫化钼的各种纳米摩擦机理,阐述了通过机械剥离法、锂离子插层法、水热法等制备纳米二硫化钼的方法;总结了纳米MoS_2在润滑领域的应用,阐述了利用表面修饰以及制备复合材料的方法可提高二硫化钼在润滑油中的分散稳定性;并指出了纳米MoS_2作为高性能润滑材料仍需解决的问题及未来的研究趋势。
        As a typical graphene-like two-dimensional(2D)layered nanomaterials,molybdenum disulfide(MoS_2)has recently evoked enormous research enthusiasm in the field of electricity,optics,thermology and mechanics due to its unique properties.In this review,we summarize the state-of-art studies of MoS_2 as lubricatant additives,aiming to give an over view of this emerging material and discuss the challenges and opportunities in this promising research area.Not only the structure,characterization and preparation,but also the recent achievements of molybdenum disulfide nanosheets are discussed.

引文

1 Xiao H,Liu S.Materials&Design,2017,135,319.
    2 Zhang X,Lai Z,Tan C,et al.Angewandte Chemie International Edition,2016,55(31),8816.
    3 Chen X,McDonald A R.Advanced Materials,2016,28(27),5738.
    4 Kalin M,Kogov2ek J,Rem2kar M.Wear,2012,280,36.
    5 张平余,薛群基,张治军,等.电子显微学报,1996(6),549.
    6 Tannous J,Dassenoy F,Lahouij I,et al.Tribology Letters,2011,41(1),55.
    7 Joly-Pottuz L,Dassenoy F,Belin M,et al.Tribology Letters.2005,18(4),477.
    8 欧忠文,徐滨士,丁培道,等.材料导报,2000,14(8),28.
    9 Rosentsveig R,Gorodnev A,Feuerstein N,et al.Tribology Letters,2009,36(2),175.
    10 Novoselov K S,Geim A K,Morozov S V,et al.Science,2004,306(5696),666.
    11 Grayfer E D,Kozlova M N,Fedorov V E.Advances in Colloid and Interface Science,2017,245,40.
    12 张虹,岳红彦,黄硕,等.材料导报:综述篇,2015,29(7),58.
    13 胡平,陈震宇,王快社,等.化工学报,2017,68(4),1286.
    14 Xia J,Wang J,Chao D,et al.Nanoscale,2017,9(22),7533.
    15 Amini M,Sa A R,Faghihi M,et al.Ultrasonics Sonochemistry,2017,39,188.
    16 马浩,杨瑞霞,李春静.材料导报,2017,31(3),7.
    17 陈九菊,修可白,孟庆刚.黑龙江工程学院学报,2010,24(3),72.
    18 白鸽玲,吴壮志.润滑与密封,2013,38(4),93.
    19 吴会杰,李元,李庆.化工新型材料,2016,44(9),16.
    20 万庆明,金翼,丁玉龙.润滑与密封,2013(6),17.
    21 Chen X,Berner N C,Backes C,et al.Angewandte Chemie International Edition,2016,55(19),5803.
    22 Xu B,Su Y,Li L,et al.Sensors and Actuators B:Chemical,2017,246,380.
    23 Voiry D,Goswami A,Kappera R,et al.Nature Chrmistry,2015,7,45.
    24 Knirsch K C,Berner N C,Nerl H C,et al.ACS Nano,2015,9(6),6018.
    25 Backes C,Berner N C,Chen X,et al.Angewandte Chemie,2015,54(9),2638.
    26 Lu F,Du H,et al.Journal of Nanomaterials,2016,2016,1.
    27 Presolski S,Wang L,Loo A H,et al.Chemistry of Materials,2017,29(5),2066.
    28 Chen Z,Yan H,Liu T,et al.Composites Science and Technology.2016,125,47.
    29 Zhang M,Chen B,Yang J,et al.RSC Advances,2015,5(109),89682.
    30 Hou Kaiming,et al.Carbon,2017,115,83.
    31 Song H,Wang B,Zhou Q,et al.Applied Surface Science,2017,419,24.