应用羧基化多壁碳纳米管(c-MWCNT)修饰碳糊电极,测定食盐中的碘酸根含量.在0.1 mol/L的NaOH电解液中,当IO3-在羧基化多壁碳纳米管修饰碳糊电极表面富集60 s,电位扫速为300 mV/s时,该修饰电极在线性扫描伏安图上能出现一灵敏的阴极溶出峰,峰电位为-0.52 V,峰电流与IO3-浓度在8.0×10-10~5.0×10-8mol/L和1.0×10-7~3.0×10-6mol/L的范围内成良好线关系,相关系数分别为0.999和0.998,检出限可达1.0×10-11mol/L;该修饰电极无汞,稳定性较好,用于加碘食盐中碘酸根含量的测定灵敏度高,平均回收率为101.1%.循环伏安(CV)测试表明,碘酸根在修饰电极上电化学反应是一不可逆过程,其电极反应标准均相速率常数为0.0109 cm.s-1.
李俊华
,
张复兴
,
王剑秋
,
许志锋
,
曾荣英
. 羧基化碳纳米管修饰碳糊电极伏安法测定食盐中碘酸根[J]. 电化学, 2008
, 14(4)
: 436
-440
.
DOI: 10.61558/2993-074X.1938
A highly-sensitive and mercury-free method of determining iodate ion in table salt was established based on carboxylic carbon nanotubes modified carbon paste electrode.In 0.1 mol/L NaOH solution,there was a sensitive cathodic stripping peak on voltammograms.The stripping peak potential was-0.52 V when accumulation time of IO-3 at the modified electrode was 60 s and the potential scan rate was 300 mV/s.There was a good liner relationship between the peak current and IO-3 concentration in the range of 8.0×10-10 ~ 5.0×10-8 mol/L and 1.0×10-7 ~ 3.0×10-6 mol/L with the correlation coefficient of 0.999 and 0.998,respectively.The detection limit was 1.0 × 10-11 mol/L.This proposed method had been applied for determination of IO-3 content for the table salt sample and the average recovery was 101.1%.The results of CV test that indicated the electrochemical reaction of iodate ion at the modified electrode was irreversible.The standard rate constant of the cathodic electrode reaction was determined to be 0.0109 cm·s-1.
[1]Xu Mao-rong(徐茂蓉).Spectrophotometric determina-tion of iodine by oxidation-decoloration of rhodamine B[J].Chinese Journal of Spectroscopy Laboratory,2003,20(1):92-94.
[2]Gao Jia-you(高甲友).Determination of trace iodate ionby fluorescence quenching method[J].Metallurgical A-nalysis,2003,23(3):38-40.
[3]Ni Hong-gang(倪宏刚),Zheng Jian-bin(郑建斌).Oscillo-voltammetric determination of iodine in table saltspiked with potassium iodate[J].PTCA,2006,42(7):569-571.
[4]Song Yuan-zhi(宋远志).Voltammetric behavior of io-dine at glassy carbon mercury membrane electrode andits applications[J].PTCA,2005,41(11):823-826.
[5]Liu Ning(刘宁),Song Jun-Feng(宋俊峰).Determi-nation of free calcium at a carbon paste electrode ad-sorptive stripping voltammetric method[J].Chinese JAnal Chem,2005,33(9):1261-1264.
[6]Li Yu-ping(李玉平),Cao Hong-bin(曹宏斌),ZhangYi(张懿).Direct electrochemistry of hemoglobin im-mobilized on carbon paste electrode modified by carbonnanotubes[J].Acta Phys-Chim Sin,2005,21:187-191.
[7]Wang Hong-juan(王红娟),Zhou Chun-mei(周春梅),Yu-Hao(余皓),et al.MWNTs modified GC electrodefor hydrogen peroxide determination[J].Electrochemis-try,2007,13(1):72-76.
[8]Zhang Lu(张璐),Zhang Yao-dong(张耀东),QiHong-lan(漆红兰).Determination of malathion basedon carbon nanotubes modified electrode incorporatingacetylcholinesterasen[J].Electrochemistry,2007,13(4):431-435.
[9]Dong Jun(董军),Heng Xiao-ying(何晓英).Investi-gation on the effects of Nitric acid treatment on carboxylgroups in multi-wall carbon nanotubes[J].Journal ofHainan Normal University,2006,19(4):342-345.
[10]Luo Hong-Xia(罗红霞),Shi Zu-Jin(施祖进),LiNan-Qiang(李南强),et al.Investigation on the elec-trochemical and electrocatalytic behavior of chemicallymodified electrode of single wall carbon nanotube func-tionalized with carboxylic acid group[J].Chem J Chi-nese Universities,2000,21(9):1372-1374.
[11]Allen J Bard,Larry R Faulkner.Electrochemicalmethods:fundamentals and applications[M].Hobo-ken:John Wiley?Sons,2001:236.
