物理化学学报
物理化學學報
물이화학학보
ACTA PHYSICO-CHIMICA SINICA
2014年
12期
2328-2334
,共7页
李晶晶%栗源%王爱玲%屈燕荣%岳彬%周丹%褚海斌%赵永亮
李晶晶%慄源%王愛玲%屈燕榮%嶽彬%週丹%褚海斌%趙永亮
리정정%률원%왕애령%굴연영%악빈%주단%저해빈%조영량
铕配合物%等离子体共振%AgSiO2纳米粒子%发光强度%核壳结构
銪配閤物%等離子體共振%AgSiO2納米粒子%髮光彊度%覈殼結構
유배합물%등리자체공진%AgSiO2납미입자%발광강도%핵각결구
Europium complex%Plasmon resonance%AgSiO2 nanoparticle%Luminescence intensity%Core-shel structure
分别制备了二氧化硅壳层厚度为10、25和80 nm的三种Ag@SiO2纳米粒子,合成了铕与不同比例苯甲酸根(BA)的配合物、铕与1,10-邻菲罗啉(phen)及2,2′-联吡啶(bpy)的配合物,并对其进行表征.表征结果推测配合物的组成为Eu(BA)nCl3-n?2H2O (n=1,2,3)、Eu(phen)Cl3?2H2O和Eu(bpy)Cl3?2H2O.配合物的荧光光谱显示,在加入Ag@SiO2纳米粒子后,复合物的荧光强度有不同程度的增加,这可能是由于表面等离子体共振造成的.不同硅壳厚度的Ag@SiO2纳米粒子的荧光增强顺序是25 nm>80 nm>10 nm,这表明二氧化硅核壳厚度约25 nm时有较强的表面等离子体共振效应.此外,在这些复合物中, Eu(phen)Cl3?2H2O复合物的增强效果是最强的,而Eu(BA)nCl3-n?2H2O的增强效果是最弱的.在三个苯甲酸铕配合物中, Eu(BA)3?2H2O的增强效果最弱,其他两个苯甲酸铕复合物增强效果相对较好.原因可能是含氮配合物(Eu(phen)Cl3?2H2O和Eu(bpy)Cl3?2H2O)可以和Ag@SiO2更好地成键,而苯甲酸铕配合物和Ag@SiO2纳米粒子的作用相对较弱. Ag@SiO2纳米粒子有望应用于增强稀土材料的发光.
分彆製備瞭二氧化硅殼層厚度為10、25和80 nm的三種Ag@SiO2納米粒子,閤成瞭銪與不同比例苯甲痠根(BA)的配閤物、銪與1,10-鄰菲囉啉(phen)及2,2′-聯吡啶(bpy)的配閤物,併對其進行錶徵.錶徵結果推測配閤物的組成為Eu(BA)nCl3-n?2H2O (n=1,2,3)、Eu(phen)Cl3?2H2O和Eu(bpy)Cl3?2H2O.配閤物的熒光光譜顯示,在加入Ag@SiO2納米粒子後,複閤物的熒光彊度有不同程度的增加,這可能是由于錶麵等離子體共振造成的.不同硅殼厚度的Ag@SiO2納米粒子的熒光增彊順序是25 nm>80 nm>10 nm,這錶明二氧化硅覈殼厚度約25 nm時有較彊的錶麵等離子體共振效應.此外,在這些複閤物中, Eu(phen)Cl3?2H2O複閤物的增彊效果是最彊的,而Eu(BA)nCl3-n?2H2O的增彊效果是最弱的.在三箇苯甲痠銪配閤物中, Eu(BA)3?2H2O的增彊效果最弱,其他兩箇苯甲痠銪複閤物增彊效果相對較好.原因可能是含氮配閤物(Eu(phen)Cl3?2H2O和Eu(bpy)Cl3?2H2O)可以和Ag@SiO2更好地成鍵,而苯甲痠銪配閤物和Ag@SiO2納米粒子的作用相對較弱. Ag@SiO2納米粒子有望應用于增彊稀土材料的髮光.
분별제비료이양화규각층후도위10、25화80 nm적삼충Ag@SiO2납미입자,합성료유여불동비례분갑산근(BA)적배합물、유여1,10-린비라람(phen)급2,2′-련필정(bpy)적배합물,병대기진행표정.표정결과추측배합물적조성위Eu(BA)nCl3-n?2H2O (n=1,2,3)、Eu(phen)Cl3?2H2O화Eu(bpy)Cl3?2H2O.배합물적형광광보현시,재가입Ag@SiO2납미입자후,복합물적형광강도유불동정도적증가,저가능시유우표면등리자체공진조성적.불동규각후도적Ag@SiO2납미입자적형광증강순서시25 nm>80 nm>10 nm,저표명이양화규핵각후도약25 nm시유교강적표면등리자체공진효응.차외,재저사복합물중, Eu(phen)Cl3?2H2O복합물적증강효과시최강적,이Eu(BA)nCl3-n?2H2O적증강효과시최약적.재삼개분갑산유배합물중, Eu(BA)3?2H2O적증강효과최약,기타량개분갑산유복합물증강효과상대교호.원인가능시함담배합물(Eu(phen)Cl3?2H2O화Eu(bpy)Cl3?2H2O)가이화Ag@SiO2경호지성건,이분갑산유배합물화Ag@SiO2납미입자적작용상대교약. Ag@SiO2납미입자유망응용우증강희토재료적발광.
Three types of Ag@SiO2 nanoparticles with silica shel thicknesses of around 10, 25, and 80 nm were prepared. Europium complexes with benzoate (BA) in different proportions, 1,10-phenanthroline (phen) and 2,2'-bipyridine (bpy), were synthesized and characterized. The results suggest that the complexes have the formulas Eu(BA)nCl3-n?2H2O (n=1, 2, 3), Eu(phen)Cl3?2H2O, and Eu(bpy)Cl3?2H2O. The luminescence spectra of the complexes showed that adding Ag@SiO2 nanoparticles increased the fluorescence intensity. The fluorescence enhancement sequence of the different silica shel thickness Ag@SiO2 nanoparticles was 25 nm>80 nm>10 nm, which showed that the local surface plasmon resonance was strongest at the silica shel thickness of about 25 nm. Furthermore, the enhancement effect for the Eu(phen)Cl3?2H2O complex was the strongest and that for the benzoic complex Eu(BA)nCl3-n?2H2O was the weakest in these complexes. For the three benzoic complexes, the enhancement effect of Eu(BA)3?2H2O was the lowest. The nitrogenous complexes (Eu(phen)Cl3 and Eu(bpy)Cl3) could combine with Ag@SiO2 nanoparticles very wel , while the interaction of Eu(BA)3?2H2O with Ag@SiO2 nanoparticles was weaker. Ag@SiO2 nanoparticles are expected to enhance luminescence of rare earth materials.