Department of Chemistry, Georgia Southern University, Statesboro, GA 30458, United States.
J Colloid Interface Sci. 2013 Jan 15;390(1):242-9. doi: 10.1016/j.jcis.2012.09.053. Epub 2012 Oct 3.
A novel liquid chromatographic (LC) method with repeated injections of Suwannee River Fulvic Acid (SRFA) was used to investigate its adsorptive fractionation by synthetic α-Al(2)O(3). Eluent (i.e., non-retained) SRFA for each injection was monitored by two ultraviolet (UV) absorbance detection channels (300 and 365 nm) and one fluorescence detection channel (λ(ex)=350 nm, λ(em)=450 nm). Preferential adsorption of SRFA constituents was revealed by the different responses of the three LC detection channels. Samples of non-retained SRFA from injections of three independent replicate experiments were collected and aggregated for subsequent analysis by steady state ultraviolet-visible (UV/vis) absorption spectrometry and size exclusion chromatography (SEC). The ratio of absorbance at 254 and 204 nm, a surrogate for specific UV absorbance at 254 nm, increased with increasing injection number for the non-retained SRFA, indicating the preferential adsorption of SRFA constituents containing aromatic moieties. SEC analysis confirmed the preferential adsorption of higher molecular weight (MW) SRFA constituents as the non-adsorbed SRFA fractions increased in MW across the series of injections. The SEC results also suggested that certain SRFA constituents in the ca. 2-5 kDa MW range adsorbed in early injections were displaced by higher MW species (ca. 5-10 kDa) in later injections.
采用新型重复进样的液相色谱 (LC) 法,结合苏万尼河腐殖酸 (SRFA),研究其对合成α-Al(2)O(3)的吸附分馏作用。每次进样的洗脱液(即未保留的 SRFA)通过两个紫外 (UV) 吸收检测通道(300nm 和 365nm)和一个荧光检测通道(λ(ex)=350nm,λ(em)=450nm)进行监测。通过三种 LC 检测通道的不同响应,揭示了 SRFA 成分的优先吸附。收集来自三个独立重复实验的未保留 SRFA 的注射样本,并进行聚集,以便随后通过稳态紫外-可见 (UV/vis) 吸收光谱法和尺寸排阻色谱 (SEC) 进行分析。254nm 和 204nm 处吸光度的比值(代表 254nm 处特定紫外吸光度的替代值)随着非保留 SRFA 的进样次数增加而增加,表明含有芳香族结构的 SRFA 成分优先吸附。SEC 分析证实,随着非吸附 SRFA 分数在分子量系列进样过程中增加,较高分子量 (MW) 的 SRFA 成分优先吸附。SEC 结果还表明,在早期进样中吸附的约 2-5kDa MW 范围内的某些 SRFA 成分被较高 MW 物种(约 5-10kDa)取代。
