氨基酸在固体表面的吸附*

介绍了氨基酸在固体表面吸附的常见吸附模式和吸附等温线类型。在常见的等温式中Sips等温式能处理液相中吸附质浓度从低到高、吸附剂表面从均匀到不均匀等各种情形下的固/液吸附体系,得到的等温线一般归属4类：S型、L型、H型和C型;总结和讨论了各吸附参数对氨基酸吸附的影响,具体考察了氨基酸种类、固体表面的性质、溶剂种类、介质的pH、介质离子强度和温度等因素对氨基酸吸附的影响,指出通过优化各吸附参数,可以调整氨基酸和固体吸附剂之间的静电吸引力或疏水作用,达到最好的吸附效果;对氨基酸的固体吸附剂进行了分类阐述。     

氨基酸在固／水界面的吸附作用

本文研究了活性炭、硅胶和氧化铝自水中吸附酪氨酸和苯丙氨酸。所得的结构表明,（1）在活性炭/水界面上两种氨基酸的吸附等温线均为Langmuir型。极限吸附量nm^S、吸附常数b与介质pH值关系曲线大约在氨基酸等电点处有最大值,这可用介质pH对氨基酸溶解度的影响解释。在活性炭表面,氨基酸主要以两性离子躺方式吸附。（2）在硅胶（氧化铝）/水界面上的吸附等温线为S型,吸附量仅为在活性炭/水界面上的1‰,在硅胶表面苯丙氨酸主要以电性作用吸附;在氧化铝表面酪氨酸以两性离子与表面形成氨键吸附。     

AAS新型吸附树脂对苯丙氨酸、酪氨权的吸附分离性能的研究

研究了AASⅠ、AASⅡ两系列新型吸附树脂对苯丙氨酸、酪氨酸的附分离性能，分析了树脂结构与吸附分离性能间的关系，探讨了聚苯乙烯系吸附树脂与芳香氨基酸间的作用机理。     

膨润土吸附氨基酸研究

本文用钠、钙两种类型膨润上对四种不同性质氨基酸进行了静态吸附试验，并对膨润土吸附氨基酸有关因素进行了研究。试验证明：钙膨润土吸附氨基酸能力较强，酸处理膨润土吸附性最好，等电；点时吸附量最大。在浓度为500mg·L－1pH＝7溶液中，酸处理膨润土吸附赖氨酸可达200mmol·100g－1。     

NAK-12树脂脱除蚕蛹复合氨基酸异味及褐变物质的研究

本文研究了用NAK－12吸附树脂脱除蚕蛹复合氨基酸异味及褐变色素的条件，初步分析了蚕蛹复合氨基酸异味产生的原因，实验结果表明：当流速为3BV／h时，1ml NAK-12吸附树脂能吸附1．75g蚕蛹复合氨基酸中的异味物质；能吸附1．45g蚕蛹复合氨基酸中的褐变物质。甲醇是异味物质和褐变物质的良好洗脱剂，用pH1．0的甲醇以1BV／h流速洗脱，仅用3．5BV的洗脱剂即可完全洗脱异味物质和褐变物质，蚕蛹复合氨基酸异味产生的可能机理是：加热蚕蛹复合氨基酸液时，其苯丙氨酸，蛋氨酸，蛋氨酸，异亮氨酸，亮氨酸，苏氨酸被氧化脱氨，生成挥发性醛，而其褐变则是赖氨酸，精氨酸与还原糖发生Maillard反应生成褐变物质引起的。     

AAS新型吸附树脂对苯丙氨酸、酪氨酸的吸附分离性能的研究

研究了AAS Ⅰ、AASⅡ两系列新型吸附树脂对苯丙氨酸、酪氨酸的吸附分离性能,分析了树脂结构与吸附分离性能间的关系,探讨了聚苯乙烯系吸附树脂与芳香氨基酸间的作用机理。     

碱性氨基酸离子交换平衡特性的研究

研究了碱性氨基酸与001×7阳离子交换树脂的离子交换平衡特性。测定了001×7树脂对碱性氨基酸两种价态离子的选择性吸附系数,并考察了pH和碱性氨基酸的浓度对平衡吸附量的影响,确定了离子交换的最佳pH 和碱性氨基酸的浓度。     

低浓度下离子交换树脂吸附氨基酸的机理

详细地研究了在低浓度下, 酸(碱)式或盐式强酸性阳离子和强碱性阴离子交换树脂吸附氨基酸的机理·结果表明, 氨基酸通过离子交换、离子转移和物理吸附等三种机理被离子交换树脂吸附。     

硅酸铜分离微生物发酵液中的氨基酸

采用硅酸铜对微生物发酵液中的氨基酸进行了分离研究.通过静态吸附试验考察了硅酸锌和硅酸铜对微生物发酵液中氨基酸的吸附影响.结果表明,硅酸铜比硅酸锌更适合分离发酵液中的氨基酸,并确定了以硅酸铜为填料的分离条件:上柱发酵液pH=2,流速0.2BV/h,洗脱液为1mol/L的NH4Cl.在该条件下能够一次性将3种不同的氨基酸较好的分离.     

芳香氨基酸在吸附树脂上的传质速度的研究

本文建立了测量芳香氨基酸在吸附树脂上传质速度的方法。引用Boyd方程模型测定了苯丙氨酸和酪氨酸的有效内扩散系数;研究了树脂结构与芳香氨基酸扩散速度之间的关系;同时考察了温度、pH值诸因素对扩散速度的影响。     

阴、阳离子表面活性剂混合体系在硅胶/水及硅胶/矿化水界面上的吸附

研究阴、阳离子表面活性剂混合体系(十二烷基氯代吡啶,辛基磺酸钠,辛基三乙基溴化铵/十二烷基苯磺酸钠)在硅胶,纯水和硅胶,矿化水界面上的吸附作用,探讨阴(阳)离子表面活性剂的存在对阳(阴)离子表面活性剂吸附作用的影响．结果表明,阴离子表面活性剂的存在基本不影响阳离子表面活性剂在带负电固体表面的吸附;而阳离子表面活性剂的存在却使本来吸附量就不大的阴离子表面活性剂在带负电的固体表面上不再吸附．在矿化水中阳离子表面活性剂的吸附量比在纯水中明显降低．从硅胶表面吸附机制解释了所得结果．     

一种评估阳离子交换吸附活化能的方法

Ion exchange adsorption is an important physicochemical process at solid/liquid interfaces. In this study, an approach was established to estimate the activation energy of cation exchange reaction on the charged surface, considering Hofmeister effects. The experimental results showed that Hofmeister effects strongly affect the ionic adsorption equilibrium on the charged particle surface. The position of the adsorbed counterion in the diffuse layer was predicted according to the established model, and the ion exchange activation energies for different bivalent cations were estimated via the cation exchange experiments. The activation energy decreases with increasing ion concentration, and the adsorption saturation of cations is a function of the activation energy at different concentrations. The established model of cation exchange adsorption in the present study has universal applicability in solid/liquid interface reactions.     

Thermodynamics of Adsorption of L-Amino Acids at Oil–Water Interfaces

Lowering of the interfacial tension of heptane–water, benzene–water, and nitrobenzene–water interfaces due to addition of 20 different amino acids to the aqueous phase has been measured. From the plot of surface pressure against molar concentration of amino acids, the initial slope and the surface excess ₂ ¹ for different amino acids have been calculated using the Gibbs adsorption equation. ₂ ¹ for most amino acids at benzene–water and heptane–water interfaces was found to be positive, with only a few being negative. At the nitrobenzene–water interface, both positive and negative ₂ ¹ values were observed. The area per adsorbed molecule at surface saturation A _m was found to vary widely, indicating different orientations of amino acid molecules at the interfaces. Using the integrated form of the Gibbs adsorption equation, the standard Gibbs energy change G ^o in kJ-m² of the adsorbed surface have been calculated for various interfaces. G ^o was found to vary linearly with the ₂ ¹ of different amino acids and the slope of the line, designated as –G _B ⁰ was found to be 22 kJ-mol^–1 for heptane–water, 23.2 kJ-mol^–1 for benzene–water, and 19.3 kJ-mol^–1 for nitrobenzene–water interfaces, irrespective of the nature of the amino acid. The origin of the linear scale of the Gibbs energy for heptane–water, benzene–water and nitrobenzene–water interfaces has been discussed in terms of hydrophobic and other interactions.     

Structural information of mussel adhesive protein Mefp-3 acquired at various polymer/Mefp-3 solution interfaces

Mytilus edulis foot protein Mefp-3 serves as a primer in the formation of adhesive plaques that attach the mussel to solid surfaces in its immediate environment. The adsorption behavior of this protein on various materials of different hydrophobicity was studied using sum frequency generation (SFG) vibrational spectroscopy. By collecting SFG signals from side chains of these amino acids and from secondary structures of the protein, we have determined that this protein adopts different conformations at different interfaces, depending on hydrophobicity of the contact medium and specific chemical group interactions. We have also demonstrated that SFG has the potential to track the interfacial conformations of a single amino acid in a protein.     

Effect of Structure on the Adsorption of Amino Acids on Copper Electrodes

The adsorption of amino acids on copper electrodes was studied at negative potentials. The effect of the amino acid structure on the mechanism and extent of adsorption was elucidated. Glycine, alanine, and asparagine molecules were found to reorient upon adsorption. An adsorption mechanism involving either neutral molecules or anions was proposed.     

The effect of solvation processes on amino acid‐ and peptide‐silica stationary phases

The surface excess adsorption isotherms of water, acetonitrile, and methanol from binary hydro‐organic mobile phases were investigated on nine home‐made stationary phases with chemically bonded amino acids, dipeptides, and tripeptides using the dynamic minor disturbance method. The stationary phases were modified by the following amino acids: glycine, alanine, phenylalanine, leucine, and aspartic acid. We investigated the influence of the type of immobilized amino acids, in particular their different side chains, on the solvent adsorption. The interpretation of solvation phenomena shows significant accumulation of investigated solvents on the adsorbent surface according to their hydrophilic or hydrophobic properties. Moreover, the accumulated amount was dependent on the length and type of amino acid sequences bonded to the silica surface. Stationary phases with bonded amino acids and peptides show stronger water and acetonitrile adsorption in contrast to the stationary phase modified with aminopropyl groups—a support for the synthesis. The comparison of water and acetonitrile adsorption as well as a data obtained with the two‐site adsorption model reveal and confirm the heterogeneity of chemically bonded phases. As a consequence of performed investigations, the classification of tested stationary phases for the potential usage in particular high‐performance liquid chromatography mode was also accomplished.     

Anion chelation by amido acid functionalized fused quartz/water interfaces studied by nonlinear optics

We report resonantly enhanced surface second harmonic generation (SHG) measurements to track the interaction of the EPA priority toxic metal pollutant chromium(VI) with fused quartz/water interfaces containing tailor-made amino acids that serve as model systems for environmental and biological interfaces. chi3 measurements of amido acid functionalized fused quartz/water interfaces are consistent with two acid-base equilibria, suggesting the formation of a laterally hydrogen-bonded environment similar to what is observed for aliphatic carboxylic acids. Chromate adsorption isotherms recorded at pH 7 are suggestive of an intramolecular chelation mechanism that becomes important when four or more hydrogen-bonding moieties are displayed toward the incoming chromate. The strong binding affinities of the amido acid functionalized fused quartz/water interfaces toward chromate are consistent with nearly 50% slower transport rates with respect to free-flowing groundwater, indicating that, in the absence of redox processes, peptide materials in heterogeneous geochemical environments can significantly increase chromate residence times. The strong evidence for synergistic effects dominating the interactions of chromate with surface-bound amido acids indicates that chemical complexity can be systematically addressed using tailor-made organic surfaces and interfaces.     

接枝微粒材料P4VP-SiO_2对酸性氨基酸的吸附性能与吸附机理

将4-乙烯基吡啶(4VP)接枝聚合于微米级硅胶表面,制得了接枝有聚4-乙烯基吡啶(P4VP)的接枝微粒P4VP-SiO_2,测定了P4VP-SiO_2的红外光谱,袁征了其化学结构,并测定了该复合型功能微粒材料的Zeta电位.采用静态法研究了P4VP-SiO_2对酸性氨基酸天冬氨酸与谷氨酸的吸附性能,考察了介质pH、离子强度及温度对其吸附性能的影响,探索了吸附机理.研究结果表明:在较大的pH范围内,P4VP-SiO_2的Zeta电位为较高的正值,即微粒表面携带有高密度的正电荷;酸性氨基酸天冬氨酸与谷氨酸等电点都较低,所以在一般的介质pH范围内,它们的分子带有负电荷;凭借静电相互作用,P4VP-SiO_2对酸性氨基酸天冬氨酸与谷氨酸均表现出很强的吸附能力,而对中性与碱性氨基酸(在一般的介质pH范围内分子带有正电荷)的吸附能力则很弱;随介质pH的增大,P4VP-SiO_2对天冬氨酸与谷氨酸的吸附能力呈现先增强后减弱的规律,在pH＝4处,吸附容量具有最大值,分别为280 mg/g与230 mg/g;温度升高,吸附容量减小;盐度增大,吸附容量降低.