基于P_2Mo_(18)O_(62)~(6-)@Tb~(3+)溶液可逆变色-荧光开关性质对维生素C和H_2O_2的光谱检测

详细信息    查看全文 | 推荐本文 |

英文篇名：Spectral Detection for Vitamin C and H_2O_2 Based on the Reversible Color Change and Luminescent Switching Properties of P_2Mo_(18)O_(62)~(6-)@Tb~(3+) Mixed Solution 作者：王斌 ; 王晓红 ; 段莉梅 ; 许良 ; 赵鹏 ; 菅金鹏 ; 刘宗瑞 英文作者：WANG Bin;WANG Xiaohong;DUAN Limei;XU Liang;ZHAO Peng;JIAN Jinpeng;LIU Zongrui;College of Chemistry and Chemical Engineering,Inner Mongolia University for the Nationalities;Inner Mongolia Key Lab of Carbon Nanomaterials; 关键词：多金属氧酸盐 ; 维生素C ; 刺激响应 ; 荧光开关 ; 生化传感 英文关键词：Polyoxometalates;;Vitamin C;;Stimuli-response;;Fluorescence switch;;Biochemical sensor 中文刊名：GDXH 英文刊名：Chemical Journal of Chinese Universities 机构：内蒙古民族大学化学化工学院;内蒙古自治区纳米碳材料重点实验室; 出版日期：2019-04-10 出版单位：高等学校化学学报 年：2019 期：v.40 基金：国家自然科学基金(批准号:21501102,21661026);; 内蒙古自治区自然科学基金(批准号:2015BS0207,2017MS0208);; 内蒙古自治区高等学校“青年科技英才支持计划”项目(批准号:NJYT-18-B22);; 内蒙古自治区纳米碳材料重点实验室开放课题(批准号:MDK2017025)资助~~ 语种：中文; 页：GDXH201904009 页数：9 CN：04 ISSN：22-1131/O6 分类号：70-78

摘要

基于变色多酸P_2Mo_(18)O_(62)~(6-)与绿光Tb~(3+)之间的功能互补及分子间能量转移的原理,在维生素C(VC)的还原下,P_2Mo_(18)O_(62)~(6-)@Tb~(3+)溶液由浅黄色变为蓝色,发生荧光猝灭;相反,在H_2O_2氧化下,溶液的蓝色褪去,荧光得以恢复,P_2Mo_(18)O_(62)~(6-)@Tb~(3+)溶液呈现出可逆的化学响应变色及荧光开关性质.利用紫外-可见(UV-Vis)及荧光(PL)光谱法对VC浓度进行定量检测,分别以800 nm处的吸光度和547 nm处荧光强度的对数值对VC浓度作图,获得光谱法对VC检测的线性方程,检出限分别为3. 40×10~(-3)和0. 21μmol/L;利用UV-Vis及PL动力学方法对VC和H_2O_2检测的响应速度进行了考察,响应时间分别为52和320 s;通过UV-Vis光谱及动力学方法考察了VC检测的选择性及可重复使用性.
        Based on the functional complementarity and energy transfer between the reversible discoloration polyoxoanions P_2Mo_(18)O_(62)~(6-) and green luminescent Tb~(3+) ions,the color of the P_2Mo_(18)O_(62)~(6-)@ Tb~(3+) mixed solution changed from light yellow to dark blue and as meanwhile the luminescence quenched under the reduction of VC. On the contrary,the dark blue color faded and the luminescence recovered correspondingly under the oxidation of H_2O_2. And the P_2Mo_(18)O_(62)~(6-)@Tb~(3+) mixed solution exhibited a reversible chemical response discoloration and luminescent switching properties. The VC concentrations were quantitatively measured by UV-Vis and PL spectroscopy,and the corresponding linear equations were acquired by drawing VC concentrations with UV-Vis absorbance at 800 nm and fluorescence intensity at 547 nm. And the detection limits were 3.40×10~(-3)and 0. 21 μmol/L,respectively. The response rates of VC and H_2O_2 detection were investigated by UV-Vis and fluorescence kinetic methods,and the response time were 52 and 320 s,respectively. Finally,the selectivity and reusability of VC detection were studied by UV-Vis spectroscopy and kinetic methods.

引文

[1]Bohndiek S.B.,Kettunen M.I.,Hu D.,Kennedy B.W.,Boren J.,Gallagher F.A.,Brindle K.M.,J.Am.Chem.Soc.,2011,133(30),11795-11801
    [2]Guo Q.H.,Wu T.T.,Liu L.J.,Hou H.Q.,Chen S.L.,Wang L.,J.Mater.Chem.B,2018,6(28),4610-4617
    [3]Zheng S.T.,Yang G.Y.,Chem.Soc.Rev.,2012,41(22),7623-7646
    [4]Yan L.L.,Liu C.G.,Jiang M.X.,Chem.J.Chinese Universities,2018,39(5),1034-1040(严玲玲,刘春光,蒋梦绪.高等学校化学学报,2018,39(5),1034-1040)
    [5]Weinstock I.A.,Schreiber R.E.,Neumann E.,Chem.Rev.,2018,118(5),2680-2717
    [6]Wang B.,Bi L.H.,Wu L.X.,J.Mater.Chem.,2011,21(1),69-71
    [7]Gu H.Y.,Bi L.H.,Fu Y.,Wang N.,Liu S.Q.,Tang Z.Y.,Chem.Sci.,2013,4(12),4371-4377
    [8]Zhai Y.L.,Zhu Z.J.,Zhu C.Z.,Zhu J.B.,Ren J.T.,Wang E.K.,Dong S.J.,Nanoscale,2013,5(10),4344-4350
    [9]Wang Z.L.,Ma Y.,Zhang R.L.,Peng A.D.,Liao Q.,Cao Z.W.,Fu H.B.,Yao J.N.,Adv.Mater.,2009,21(17),1737-1741
    [10]Qin B.,Chen H.Y.,Liang H.,Fu L.,Liu X.F.,Qiu X.H.,Liu S.Q.,Song R.,Tang Z.Y.,J.Am.Chem.Soc.,2010,132(9),2886-2888
    [11]Wang B.,Yin Z.D.,Bi L.H.,Wu L.X.,Chem.Commun.,2010,46(38),7163-7165
    [12]Gao W.M.,Yu T.,Wu L.X.,Bi L.H.,Chem.Commun.,2016,52(68),10403-10406
    [13]Gao W.M.,Yu T.,Du Y.,Wang R.Q.,Wu L.X.,Bi L.H.,ACS Appl.Mater.Interfaces,2016,8(18),11621-11628
    [14]Wang B.,Meng R.Q.,Bi L.H.,Wu L.X.,Dalton Trans.,2011,40(19),5298-5301
    [15]Zhai Y.L.,Zhu C.Z.,Ren J.T.,Wang E.K.,Dong S.J.,Chem.Commun.,2013,49(24),2400-2402
    [16]Wang B.,Wang X.H.,Wu Y.G.,Zheng J.H.,Liu Z.R.,Bi L.H.,Wu L.X.,Chinese J.Inorg.Chem.,2016,32(6),994-1000(王斌,王晓红,乌英嘎,郑金慧,刘宗瑞,毕立华,吴立新.无机化学学报,2016,32(6),994-1000)
    [17]Song C.Y.,Chai D.F.,Zhang R.R.,Liu H.,Qiu Y.F.,Guo H.D.,Gao G.G.,Dalton Trans.,2015,44(9),3997-4002
    [18]Arendt E.,Zehri S.,Eloy P.,Gaigneaux E.M.,Eur.J.Inorg.Chem.,2012,2012(16),2792-2801
    [19]Liu D.,Tan H.Q.,Chen W.L.,Li Y.G.,Wang E.B.,CrystEngComm,2010,12(7),2044-2046
    [20]Zhang Z.M.,Zhang T.,Wang C.,Lin Z.,Long L.S.,Lin W.B.,J.Am.Chem.Soc.,2015,137(9),3197-3200
    [21]Wang B.,Li B.,Hou G.F.,Li H.L.,Wang S.,Wu L.X.,Walter S.,Bi L.H.,J.Cluster Sci.,2014,25(3),741-753
    [22]Yamase T.,Chem.Rev.,1998,98(1),307-326
    [23]Ritchie C.,Moore E.G.,Speldrich M.,K9gerler P.,Angew.Chem.Int.Ed.,2010,49(42),7702-7705
    [24]Liu S.P.,XuL.,Li F.Y.,Xu B.B.,Sun Z.X.,J.Mater.Chem.,2011,21(6),1946-1952
    [25]Wang Y.Z.,Shi L.,Yang Y.,Li B.,Wu L.X.,Dalton Trans.,2014,43(35),13178-13186
    [26]Jin L.H.,Fang Y.X.,Wen D.,Wang L.,Wang E.K.,Dong S.J.,ACS Nano,2011,5(6),5249-5253