共查询到17条相似文献,搜索用时 125 毫秒
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用紫外-可见吸收光谱和荧光发射光谱研究了蒽在不同组成和结构的十二烷基硫酸钠(SDS)/苯甲醇(BA)/H20微乳液中的光谱特征,探讨了微乳液组成和结构对蒽光谱特征的影响,阐述了蒽在微乳液中的定位。结果表明,蒽位于O/W微乳液的膜相和油核;在SDS/BA/H2O W/O微乳液中,蒽定位于油连续相。 相似文献
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本文报道了Triton X-100(辛基苯基聚氧乙烯醚)/[bmim][PF6](1-丁基-3-甲基咪唑六氟磷酸盐)/水离子液体微乳液(Triton X-100/[bmim][PF6]-M)增敏荧光猝灭法测定W(Ⅵ)。该体系λex=616nm,λem=690,W(Ⅵ)含量在0.2~10.0μg/mL范围内与其荧光猝灭值(△F)符合线性关系,相关系数r=0.9984,方法检出限为0.07μg/mL。同时以荧光剂亚甲基蓝在不同介质中的荧光量子产率初步探讨了离子液体微乳液的增敏机理。该方法可用于矿样中钨含量的测定。 相似文献
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采用低能相反转法,以聚乳酸(PLA)、疏水性药物喜树碱(CPT)溶液为油(O)相,以明胶水溶液、亲水性药物黄芪多糖(APS)为水(W)相,制备水包油(O/W)初乳液.通过控制聚乙二醇(PEG)的浓度和分子量制备O/W纺丝液,经乳液静电纺丝获得PLA/PEG微纳纤维膜.采用粒径分布、光学显微镜(OM)、扫描电子显微镜(SEM)、红外光谱(FTIR)、X射线衍射(XRD)、接触角测试和细胞毒性实验对初乳液和PLA/PEG微纳纤维膜进行表征,并通过激光共聚焦显微镜(CLSM)观察药物的分布情况.结果表明,通过乳液静电纺丝可成功制备亲水性良好的不同微纳结构的PLA/PEG微纳纤维膜.PLA/PEG微纳纤维膜形貌不同,亲水性存在差异,无细胞毒性.体外药物释放结果表明,与pH=6.8和7.4的释放介质相比,在pH=5.8的释放介质中,药物累积释放率较高,表明载药PLA/PEG微纳纤维膜能够有效减缓CPT的释放,而APS释放速率较快,可实现亲疏水性药物的差别性释放. 相似文献
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在pH=6.6 的缓冲介质中, 肾上腺色腙(CBZC)与二氯荧光素(DCF)、二溴荧光素(DBF) 和二碘荧光素(DIF)通过静电引力、芳基堆积作用和范德华力形成摩尔比为2: 1的复合物, 引起上述二卤代荧光素的荧光发生猝灭, 最大猝灭波长分别位于533, 536和560 nm. 其荧光猝灭值(ΔF)在一定范围内与肾上腺色腙浓度成正比, 荧光猝灭反应具有较高的灵敏度, 对CBZC的检出限分别为3.3 ng/mL(CBZC-DCF体系), 5.7 ng/mL(CBZC-DBF体系)和129.6 ng/mL(CBZC-DIF体系). 考察了共存物质的影响、荧光猝灭反应的适宜条件和影响因素, 结果表明, 该方法具有良好的选择性, 可用于CBZC的血药和尿药浓度的快速检测. 从温度的影响、荧光寿命以及Stern-Volmer图判断该反应为静态猝灭反应. 相似文献
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利用重氮基的光分解活性、采用自组装的方法将带有功能基团NH2 的4-(4-氨基苯乙炔基)苯共价键接在石英基片上制备了共轭单分子膜; 利用膜上NH2 的反应活性, 通过酰胺化反应或自组装的方式将稠环芘修饰在单分子膜上,构筑了含有芘荧光探针的稳定发光超薄膜; 该薄膜能够与电子受体硝基苯胺间因相互作用形成电荷转移络合物而使其荧光猝灭, 并且该薄膜对硝基苯胺同分异构体的荧光猝灭响应有明显的差异, 其中对硝基苯胺对功能薄膜的猝灭效应最为明显, 其次是邻硝基苯胺和间硝基苯胺; 且具有明显的浓度依赖性. 相似文献
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通常, 微乳液一般由四个组分构成:水相、油相、表面活性剂和助表面活性剂。本文报道了一种不含表面活性剂的微乳液体系(简称SFME),由呋喃甲醛(油相),水和乙醇三组分构成,不含传统的表面活性剂。对其相行为进行了研究,发现存在一个单相微乳液区和一个两相平衡区。采用电导率法和冷冻蚀刻电镜(FF-TEM)考察了单相区域中微乳液的微结构,结果表明可分为油包水(O/W)、双连续(BC)和水包油(W/O)三个区域。液滴直径介于30~80nm。 相似文献
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通常微乳液一般由四个组分构成:水相、油相、表面活性剂和助表面活性剂。本文报道了一种不含表面活性剂的微乳液体系(简称SFME),由呋喃甲醛(油相),水和N,N-二甲基甲酰胺(DMF)三组分构成,不含传统的表面活性剂。对其相行为进行了研究,发现存在一个单相微乳液区和一个两相平衡区。采用电导率法和冷冻蚀刻电镜(FF-TEM)考察了单相区域中微乳液的微结构,结果表明可分为油包水(O/W)、双连续(BC)和水包油(W/O)三个区域。液滴直径介于40-70nm。 相似文献
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GUO Xia XU Hui GUO Rong ** Department of Chemistry Yangzhou University Yangzhou P. R. China 《高等学校化学研究》2003,19(4):484-488
IntroductionDuring the last decade,microemulsions haveplayed important roles in the development of bio-logical,material,environmental and other relatedfields[1— 4] .Although photo- induced electron trans-fer processes are of considerable interest in biologyand chemistry,up to now,most of the studies ofthe photo- induced electron transfer in micelle andinverse micelle have been limited to one- or two-component water/surfactant systems[5] .As theirextensions to microemulsion,only a very limited… 相似文献
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Spectroscopy characterization of anthracene in sodium dodecyl sulfate (SDS)/benzyl alcohol (BA)/water (H(2)O) microemulsion was studied by UV-visible absorption and fluorescence emission spectroscopy. The impact of the composition and structure of the microemulsion on spectroscopy characterization of anthracene were discussed. At the same time, we indicated the location of anthracene in microemulsion. The results indicated that in O/W microemulsion in SDS/BA/H(2)O system, anthracene exists both in the membrane phase and oil core, while in W/O microemulsion, anthracene exists in the oil continuous phase. 相似文献
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《Journal of Dispersion Science and Technology》2013,34(4):329-335
Photoinduced electron transfer reactions of anthracene with N,N-diethylaniline (DEA) and phenothiazine (PTZ) occurred in the membrane phase of the CTAB (hexadecyltrimethylammonium bromide)/n-C5H11OH (1-pentanol)/H2O micro-emulsion. DEA and PTZ exist in the membrane phase of the microemulsion because the presence of vitamin-C (Vc) can change the quenching constant. The change of the quenching constant for the DEA–anthracene system with the presence of Vc is more obvious than that for the PTZ–anthracene system. Thus, the DEA molecules are much closer to the polar head of the microemulsion than PTZ. Compared with DEA, the distribution of PTZ in the microemulsion tends to follow Poisson statistics. 相似文献
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In cetyltrimethylammonium/n-pentanol/H2O W/O (W/O = water in oil microemulsion) mixtures and bi-continuous microemulsions, phenothiazine (PTZ) molecules exist in
the membrane phase of the dispersion either with the N atom or with the S atom pointed toward the polar head of cetyltrimethylammonium
(CTAB). Cyclic voltammetry has been used to investigate the effects of the compositions and structures of the microemulsions,
pH, and the salt on the location distribution of PTZ in the membrane phase of the dispersion in CTAB/n-C5H11OH/H2O W/O and bi-continuous microemulsions. The results show that the location distribution of PTZ in the membrane phase of the
dispersion in microemulsions is mainly dependent on the hydrogen bond between PTZ and n-C5H11OH (or the counterion), and on the electrostatic attractive interaction between the N atom in PTZ and the polar head of CTAB. 相似文献
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Photoinduced electron-transfer reaction of anthracene with N,N-diethylaniline (DEA) was studied in the SDS (sodium dodecyl sulfate)/BA (benzyl alcohol)/H2O system. In an oil/water microemulsion, only the excited anthracene located at the interface can be quenched by DEA. In a water/oil microemulsion, this quenching reaction occurs in the BA continuous phase. Besides being the quencher of the excited anthracene, DEA could also change the system's structure. 相似文献
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The location of phenothiazine (PTZ) in sodium dodecyl sulfate (SDS)/n-pentanol (n-C5H11OH)/water microemulsions is studied by cyclic voltammetry at a Pt electrode. The results indicate that PTZ exists in the membrane phase of microemulsion droplets with its N atom or S atom toward the polar head of the surfactant. In addition, we examine the effect of the compositions and structures of the microemulsions, pH, temperature, and the inorganic salts on the location distribution for PTZ in the membrane phase of the microemulsions. The results show that the location distribution for PTZ in the membrane phase of the microemulsions is mainly dependent on the hydrogen bond between the -NH in PTZ and n-pentanol (or the -SO4- of SDS) and on the electrostatic interaction between the S atom (or N atom) in PTZ and the polar head of SDS. 相似文献
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A series of microemulsions, both W/O and O/W, based on nonionic surfactants of the form (NP(EO)n), were prepared using the titration method. Mixing a constant weight of surfactant with a constant volume of the dispersed phase and an initial volume of continuous phase produces an emulsion, which is titrated to clarity with another surfactant (cosurfactant). Plotting (a) the volume of cosurfactant necessary to transform an emulsion into a microemulsion containing a fixed volume of dispersed phase and constant weight of surfactant versus (b) different initial continuous-phase volumes yields a straight line. Extrapolating from experimentally determined values for the cosurfactant volume to the value corresponding to a zero-volume continuous phase allows the determination of the surfactant molar composition and the average number of ethylene oxides (EO) per nonylphenol adsorbed at the interface. Using a surfactant with the same number of ethylene oxides yields a single-surfactant microemulsion. Measurement of surfactants transmittance in the oil and water phases demonstrates that microemulsification occurs when the surfactant interfacial film is equally soluble in the two phases. Surface pressure measurements reveal that oil penetration impedes formation of O/W microemulsions with n-tetradecane or n-hexadecane as dispersed phase. Conductance, particle size, and transmittance measurements show that above a certain dispersed-phase volume percolation of the microemulsion occurs. 相似文献