金纳米棒的生长及与FeCl_3的作用

详细信息    查看全文 | 推荐本文 |

英文篇名：Growth of Gold Nanorods and Their Interaction with Ferric Chloride 作者：韩林唤 ; 李凯丰 ; 陈艳伟 英文作者：HAN Linhuan;LI Kaifeng;CHEN Yanwei;Key Laboratory of UV-Emitting Materials and Technology of Ministry of Education,School of Physics,Northeast Normal University; 关键词：金纳米棒 ; 三氯化铁 ; 刻蚀 ; 表面等离子体共振 英文关键词：Gold nanorods;;Ferric chloride;;Etching;;Surface plasmon resonance 中文刊名：GDXH 英文刊名：Chemical Journal of Chinese Universities 机构：东北师范大学物理学院紫外光发射材料与技术教育部重点实验室; 出版日期：2017-05-10 出版单位：高等学校化学学报 年：2017 期：v.38 基金：国家自然科学基金(批准号:11174047)资助~~ 语种：中文; 页：GDXH201705002 页数：7 CN：05 ISSN：22-1131/O6 分类号：16-22

摘要

采用三氯化铁选择性刻蚀法获得了预定长径比的金纳米棒.相比于晶种生长法,三氯化铁选择性刻蚀法可以更加简便快捷地调控金纳米棒形貌.以三氯化铁为刻蚀剂的刻蚀反应优先发生在金纳米棒尖端,这是因为金纳米棒尖端反应活性更高且表面活性剂钝化作用更弱.通过控制刻蚀反应时间及刻蚀剂浓度,可以精确调控金纳米棒的长径比.实验结果表明,增加刻蚀剂浓度、卤素离子浓度以及升高反应温度可以加快刻蚀反应速率.进一步讨论了金属离子的刻蚀作用机理.
        Gold nanorods(AuNRs) with predetermined aspect ratios were obtained by the ferric chloride(FeCl_3) selective etching method. Compared with the seed growth method,the FeCl_3 selective etching method is simpler and faster. The etching reaction takes place preferentially at the tip of gold nanorods due to the higher reaction activity and the less surface passivation at the tips of the gold nanorod. By controlling the reaction time and the concentration of the etchant,the aspect ratio of the gold nanorods can be precisely controlled. The experimental results show that the reaction rate increased by increasing the concentrations of the etchant and the halide ion and the reaction temperature. The mechanism of metal ion etching was also disscussed.

引文

[1]Jong B.,Kim Y.S.,Choi Y.,Small,2011,7(2),265—270
    [2]Huang C.P.,Yin X.G.,Huang H.,Zhu Y.Y.,Opt.Express,2009,17(8),6407—6413
    [3]Eustis S.,El-Sayed M.A.,Chem.Soc.Rev.,2006,35(3),209—217
    [4]Jiang X.C.,Pileni M.P.,Colloid Surface A,2007,295(1—3),228—232
    [5]Woo K.C.,Shao L.,Chen H.J.,Liang Y.,Wang J.F.,Lin H.Q.,ACS Nano,2011,5(7),5976—5986
    [6]Jin P.,Dai Z.,Guo W.J.,Chen G.P.,Chem.J.Chinese Universities,2015,36(5),844—849(金萍,代昭,郭文娟,陈广平.高等学校化学学报,2015,36(5),844—849)
    [7]Zhang L.Y.,Chi Y.N.,Shan G.Y.,Chen Y.W.,Liu N.,Chem.J.Chinese Universities,2016,37(7),1239—1244(张龄月,迟娅楠,单桂晔,陈艳伟,刘娜.高等学校化学学报,2016,37(7),1239—1244)
    [8]Zheng Z.K.,Tachikawa T.,Majima T.,J.Am.Chem.Soc.,2015,137(2),948—957
    [9]Lohse S.E.,Murphy C.J.,Chem.Mater.,2013,25(8),1250—1261
    [10]Terentyuk G.,Panfilova E.,Khanadeev V.,Chumakov D.,Genina E.,Bashkatov A.,Tuchin V.,Bucharskaya A.,Maslyakova G.,Khlebtsov N.,Khlebtsov B.,Nano Res.,2014,7(3),325—337
    [11]Maltzahn G.V.,Park J.H.,Agrawal A.,Bandaru N.K.,Das S.K.,Sailor M.J.,Bhatia S.N.,Cancer Res.,2009,69(9),3892—3900
    [12]Sugiura T.,Matsuki D.,Okajima J.,Komiya A.,Mori S.,Maruyama S.,Kodama T.,Nano Res.,2015,8(12),3842—3852
    [13]Kirui D.K.,Krishnan S.,Strickland A.D.,Batt C.A.,Macromol.Biosci.,2011,11(6),779—788
    [14]Kang H.Z.,Trondoli A.C.,Zhu.G.,Chen Y.,Chang Y.J.,Liu H.P.,Huang Y.F.,Zhang X.L.,Tan W.H.,ACS Nano,2011,5(6),5094—5099
    [15]Wu H.Y.,Huang W.L.,Huang M.H.,Cryst.Growth Des.,2007,7(4),831—835
    [16]Jean R.D.,Larsson M.,Cheng W.D.,Hsu Y.Y.,Bow J.S.,Liu D.M.,Appl.Surf.Sci.,2016,390,675—680
    [17]Han B.,Zhu Z.N.,Li Z.T.,Zhang W.,Tang Z.Y.,J.Am.Chem.Soc.,2014,136(46),16104—16107
    [18]Slaughter L.S.,Wu Y.P.,Willingham B.A.,Nordlander P.,Link S.,ACS Nano,2010,4(8),4657—4666
    [19]Murphy C.J.,Sau T.K.,Gole A.M.,Orendorff C.J.,Gao J.X.,Gou L.F.,Hunyadi S.E.,Li T.,J.Phys.Chem.B,2005,109(29),13857—13870
    [20]Wen T.,Zhang H.,Tang X.P.,Chu W.G.,Liu W.Q.,Ji Y.L.,Hu Z.J.,Hou S.,Hu X.N.,Wu X.C.,J.Phys.Chem.C,2013,117(48),25769—25777
    [21]Yang R.,Song D.,Wang C.,Zhu A.,Xiao R.,Liu J.,Long F.,RSC.Adv.,2015,5(124),102542—102549
    [22]Shen X.M.,Liu W.Q.,Gao X.J.,Lu Z.H.,Wu X.C.,Gao X.F.,J.Am.Chem.Soc.,2015,137(50),15882—15891
    [23]Tsung C.K.,Kou X.S.,Shi Q.H.,Zhang J.P.,Yeung M.H.,Wang J.F.,Stucky G.D.,J.Am.Chem.Soc.,2006,128(16),5352—5353
    [24]Sreeprasad T.S.,Samal A.K.,Pradeep T.,Langmuir,2007,23(18),9463—9471
    [25]Thota S.,Chena S.,Zhao J.,Chem.Commun.,2016,52,5593—5596
    [26]Chen S.,Thota S.,Wang X.D.,Zhao J.,J.Mater.Chem.A,2016,4,9038—9043
    [27]Liu W.Q.,Hou S.,Yan J.,Zhang H.,Jia Y.L.,Wu X.C.,Nanoscale,2016,8(2),780—784
    [28]Wilson A.,Bernard R.,Borensztein Y.,Croset B.,Cruguel H.,Vlad A.,Coati A.,Garreau Y.,Prévot G.,J.Phys.Chem.Lett.,2015,6(11),2050—2055
    [29]Jiao Z.,Xia H.,Tao X.,J.Phys.Chem.C,2011,115,7887—7895
    [30]Bai T.T.,Sun J.F.,Che R.C.,Xu L.N.,Yin C.Y.,Guo Z.R.,Gu N.,ACS Appl.Mater.Interfaces,2014,6(5),3331—3340
    [31]Zheng Z.K.,Tachikawa T.,Majima T.,J.Am.Chem.Soc.,2014,136(19),6870—6873
    [32]Stewart I.E.,Ye S.R.,Chen Z.F.,Flowers P.F.,Wiley B.J.,Chem.Mater.2015,27(22),7788—7794
    [33]Yao T.J.,Cui T.Y.,Fang X.,Cui F.,Wu J.,Chem.J.Chinese Universities,2013,34(10),2421—2426(姚同杰,崔铁钰,方雪,崔放,吴杰.高等学校化学学报,2013,34(10),2421—2426)
    [34]Xiong L.,Li S.W.,Zhang B.,Du Y.C.,Miao P.,Ma Y.,Han Y.X.,Zhao H.T.,Xu P.,RSC Adv.,2015,5(93),76101—76106
    [35]Liu C.,Jiang Q.,Chen L.,Zhang H.,Chen H.X.,Zhou J.,Ye Y.,Chem.J.Chinese Universities,2013,34(11),2488—2492(刘婵,江茜,陈蕾,张侯,陈怀侠,周吉,叶勇.高等学校化学学报,2013,34(11),2488—2492)
    [36]Jiao L.S.,Wang Z.J.,Niu L.,Shen J.,You T.Y.,Dong S.J.,Ivaska A.,J.Solid State Electrochem.,2006,10(11),886—893
    [37]Quynh L.M.,Nam N.H.,Kong K.,Nhung N.T.,Notingher I.,Henini M.,Luong N.H.,J.Electron.Mater.,2016,45(5),2563—2568