冶金分析
冶金分析
야금분석
METALLURGICAL ANALYSIS
2010年
3期
13-17
,共5页
蒋娟娟%于永丽%翟涵%徐淑坤%张秀娟
蔣娟娟%于永麗%翟涵%徐淑坤%張秀娟
장연연%우영려%적함%서숙곤%장수연
荧光探针%铬(Ⅵ)%纳米粒子%钒酸钇%铕
熒光探針%鉻(Ⅵ)%納米粒子%釩痠釔%銪
형광탐침%락(Ⅵ)%납미입자%범산을%유
fluorescence probe%ehromium(Ⅵ)%nanoparticle%yttrium vanadate%europium
水浴法合成了水溶性YVO_4:Eu荧光纳米粒子,粒子溶液荧光强度大,荧光性能稳定.以YVO_4:Eu粒子作荧光探针,基于Cr(Ⅵ)对YVO_4:Eu粒子的荧光猝灭,建立了简单快速地定量测定痕量Cr(Ⅵ)的新方法.对Cr(Ⅵ)的测定条件及共存离子的干扰进行了考察,在最佳条件下,反应溶液中YVO_4:Eu粒子荧光强度的对数值和Cr(Ⅵ)浓度有良好的线性关系,线性回归方程为1g/L=2.90-1.30×101c(c的单位:10-mol/L),线性相关系数为0.997 1,线性范围为1.04×10~(-4)~5.20×10~(-2)g/L.方法的检出限为1.6×10~(-5)g/L,RSD为1.7%(5.20×10~(-3)g/L,n-11).将方法用于测自来水样中Cr(Ⅵ),回收率为102%~109%.实验探讨了Cr(Ⅵ)对YVO_4:Eu粒子荧光猝灭的机理,结果表明是静态猝灭.
水浴法閤成瞭水溶性YVO_4:Eu熒光納米粒子,粒子溶液熒光彊度大,熒光性能穩定.以YVO_4:Eu粒子作熒光探針,基于Cr(Ⅵ)對YVO_4:Eu粒子的熒光猝滅,建立瞭簡單快速地定量測定痕量Cr(Ⅵ)的新方法.對Cr(Ⅵ)的測定條件及共存離子的榦擾進行瞭攷察,在最佳條件下,反應溶液中YVO_4:Eu粒子熒光彊度的對數值和Cr(Ⅵ)濃度有良好的線性關繫,線性迴歸方程為1g/L=2.90-1.30×101c(c的單位:10-mol/L),線性相關繫數為0.997 1,線性範圍為1.04×10~(-4)~5.20×10~(-2)g/L.方法的檢齣限為1.6×10~(-5)g/L,RSD為1.7%(5.20×10~(-3)g/L,n-11).將方法用于測自來水樣中Cr(Ⅵ),迴收率為102%~109%.實驗探討瞭Cr(Ⅵ)對YVO_4:Eu粒子熒光猝滅的機理,結果錶明是靜態猝滅.
수욕법합성료수용성YVO_4:Eu형광납미입자,입자용액형광강도대,형광성능은정.이YVO_4:Eu입자작형광탐침,기우Cr(Ⅵ)대YVO_4:Eu입자적형광졸멸,건립료간단쾌속지정량측정흔량Cr(Ⅵ)적신방법.대Cr(Ⅵ)적측정조건급공존리자적간우진행료고찰,재최가조건하,반응용액중YVO_4:Eu입자형광강도적대수치화Cr(Ⅵ)농도유량호적선성관계,선성회귀방정위1g/L=2.90-1.30×101c(c적단위:10-mol/L),선성상관계수위0.997 1,선성범위위1.04×10~(-4)~5.20×10~(-2)g/L.방법적검출한위1.6×10~(-5)g/L,RSD위1.7%(5.20×10~(-3)g/L,n-11).장방법용우측자래수양중Cr(Ⅵ),회수솔위102%~109%.실험탐토료Cr(Ⅵ)대YVO_4:Eu입자형광졸멸적궤리,결과표명시정태졸멸.
Water-soluble YVO_4:Eu fluorescent nanoparticles were synthesized by water-bath heating method. The fluorescent intensity of nanoparliele solution is high and stable. It was found that the fluorescence of YVO_4:Eu solution could be quenched by chromium(Ⅵ), and thus a simple and quick method to determine trace ehromium(Ⅵ) by using YVO-4 :Eu as fluorescence probe was established. The determination conditions and the interference of coexisting ions were investigated. Under the opti-mized conditions, the logarithm of fluorescent intensity of YVO_4 : Eu nanopartieles in reaction solu-tions is proportional to the concentration of ehromium(Ⅵ) in the range of 1.04 × 10~(-4)-5.20 × 10~(-2) g/L and the linear regression equation is lgI=2.90-1.30 × 10~(-3) c (the unit of c: 10~(-6) mol/L) with the correlation coefficient of 0. 997 1. The detection limit of the method is 1, 6 × 10~(-5) g/L and RSD is 1.7 % for 5.20×10~(-3) g/L ehromium(Ⅵ) (n=11). The method has been applied to determine chromi-um(Ⅵ) in tap water and the recoveries were between 102 % and 109 %. The mechanism of fluorescence quenching by ehrornium (Ⅵ) was also studied, and it was proved that the mechanism is static quench-ing.