离子交换树脂去除模拟放射性废液中的铯

核电站放射性废液组成复杂,其中¹³⁷Cs、⁹⁰Sr和⁶⁰Co是放射性废液处理的主要目标。 本文采用稳定同位素模拟放射性废液,研究了Cs⁺离子在强酸性阳离子树脂IRN97中的交换等温线、动力学特性以及固定床穿透行为,探讨了共存的硼酸和Sr²⁺、Co²⁺等核素离子对Cs⁺离子交换行为的影响。 结果表明,废液中存在的高浓度硼酸在一定程度上会减小树脂对Cs⁺的交换量;与共存的Sr²⁺和Co²⁺离子相比,虽然Cs⁺的交换速率快,但树脂对Sr²⁺和Co²⁺的选择性更高,因此在达到交换平衡状态下,Sr²⁺和Co²⁺的交换容量大于Cs⁺;在采用固定床吸附柱进行的动态吸附中,提高Cs⁺的进水浓度可以提高树脂的利用率。     

两例新的镧系金属-有机框架化合物高效去除Cs+离子研究※

¹³⁷Cs具有强放射性和较长半衰期, 一旦从核废液中泄露将对人类健康和环境造成很大危害. 由于¹³⁷Cs⁺的高溶解性、易迁移性和废液中干扰离子的影响, 从复杂的放射性废液中有效去除¹³⁷Cs⁺仍然是一个挑战. 本研究通过溶剂热法合成了两例新的三维微孔镧系金属-有机框架化合物(Me₂NH₂)_0.5(H₃O)_0.25Na_0.25Ln(OH)(stp)•0.25H₂O (FJSM-LnMOF; Ln=Eu, Tb; H₃stp=2-磺酸基对苯二甲酸), 它们具有良好的水稳定性和一定的耐酸碱性. FJSM-EuMOF和FJSM-TbMOF对Cs⁺离子吸附具有快速的动力学和高的吸附量(q_m^Cs分别为229.25和211.28 mg/g). 它们对Cs⁺离子具有良好的选择性(K_d^Cs值高达2.18×10³ mL/g). 即使在Na⁺, K⁺, Mg²⁺, Ca²⁺离子干扰的情况下, 它们仍然表现出对Cs⁺离子的选择性吸附性能. 我们成功获得了Cs⁺吸附产物的单晶结构, 通过单晶结构分析结合X射线光电子能谱(XPS), 红外(IR), 扫描电镜能量色散谱(EDS)和元素分析(EA)等多种表征方法, 证实了FJSM-EuMOF对Cs⁺离子的吸附为离子交换的机理. 结果表明, FJSM-EuMOF对Cs⁺离子的高效吸附主要源于镧系金属-有机阴离子框架中有机配体上的 COO^–和 $\text{SO}_{3}^{}$官能团对Cs⁺离子强的作用力以及通道内存在易交换的[Me₂NH₂]⁺阳离子和[H₃O]⁺离子. 这项工作表明, 镧系金属-有机框架化合物在放射性铯的修复中具有潜在的应用价值.     

NaA沸石离子交换过程的介电弛豫谱研究

在40 Hz~110 MHz频率段对不同Ca²⁺交换度的NaA沸石堆积体系进行了介电测量, 并利用Cole-Cole公式及Hanai方法对介电参数和相参数进行拟合与解析. 结果表明, 随着Ca²⁺交换度的不断增高, 堆积体系的介电增量、弛豫频率、弛豫分布系数以及粒子的电导率均有不同程度的降低, 而粒子的介电常数保持不变. 通过综合分析弛豫变化规律与离子交换度的内在联系发现, 离子交换后Ca²⁺选择六元环占位, 同时六元环和八元环位置的相邻2个Na⁺被置换; 占据六元环的Ca²⁺与八元环位置的Na⁺对沸石粒子的极化贡献等价; Ca²⁺的进入导致沸石孔道内微观电场多样化.     

碱金属离子X型沸石的固相离子交换及其催化性能的研究

本文考察了水合13X沸石与碱金属盐类间的固相离子交换反应,并对交换样品的比表面、孔容和异丙醇分解反应活性进行了测定。结果表明,这种类型的固相离子交换在室温下即可发生。体积较大的Cs^+比K^+难于交换,高温焙烧有利于有提高Cs^+的交换度。固相交换样品的比表面、孔容变化和异丙醇分解反应活性都与液相交换样品相同,只是交换度的函数,与交换方法无关。与K^+交换样品相比,Cs^+交换样品中Cs^+离子更多地占据超笼,导致更高的超笼局部碱性和脱氢反应活性。     

碱金属离子X型沸石的固相离子交换及其催化性能的研究

本文考察了水合13X沸石与碱金属盐类间的固相离子交换反应,并对交换样品的比表面、孔容和异丙醇分解反应活性进行了测定.结果表明,这种类型的固相离子交换在室温下即可发生.体积较大的Cs~+比K~+难于交换,高温焙烧有利于提高Cs~+的交换度.固相交换样品的比表面、孔容变化和异丙醇分解反应活性都与液相交换样品相同,只是交换度的函数,与交换方法无关.与K~+交换样品相比,Cs~+交换样品中Cs~+离子更多地占据超笼,导致更高的超笼局部碱性和脱氢反应活性.     

溶液中杯[4]芳烃双冠-6与Cs~+配位化学研究

研究了溶液中杯[4]芳烃双冠-6(BisC₆)与Cs⁺配位行为.常温下,BisC₆/NPME(邻硝基苯甲醚)体系单级萃铯百分率达99.36%,模拟料液中,Cs⁺/Na⁺和Cs⁺/K²⁺分离系数分别为3.92×10⁴和2.21×10⁴.局域结构模型实验表明,配合物分子中可能存在水或(和)硝酸(根).ESI-MS谱表明,NPME体系中,铯离子与BisC₆同时形成1:1(单核)和2:1(双核)的配合物,并且存在[BisC₆·H₂O],[BisC₆·Cs⁺]⁺,[BisC₆·2Cs⁺·H₂O]₂+和[BisC₆·2Cs₁₀⁺·No₁₀^-3]10⁺等多种配合物分子.EXAFS实验表明,溶液中铯离子的配位数为7,形成7个氧配位的稳定结构,ADF计算验证了EXAFS实验结果.     

改性硅藻土负载亚铁氰化铜复合物的制备及其对Cs+的吸附性能

采用水热法、以氯化铝为铝源对硅藻土(De)进行改性,通过浸渍法将亚铁氰化铜(KCu HCF)纳米颗粒负载于改性De表面,制备出γ-Al OOH/De-KCu HCF和γ-Al₂O₃/De-KCu HCF两种复合吸附剂,对所制备的吸附剂进行了表征,并研究了其对Cs⁺的吸附性能。结果表明,所制备吸附剂具有优异的Cs⁺吸附性能,γ-Al OOH/De-KCu HCF和γ-Al₂O₃/De-KCu HCF最高吸附容量分别可达75.44、84.02 mg·g^-1,γ-Al₂O₃/De-KCu HCF对模拟卤水中Cs⁺的吸附率高达97.55%;以3 mol·L^-1NH₄NO₃为脱附剂,经3级连续脱附后,γ-Al₂O₃/De-KCu HCF的Cs⁺脱附率...     

RbCl和CsCl水溶液结构的X射线散射及经验势结构精修模拟

采用X射线散射法研究了RbCl和CsCl水溶液的结构,利用基于经验势的结构精修(EPSR)方法获得了溶液中的水合Cl^-、Rb⁺、Cs⁺、离子缔合及本体水的对径向分布函数、配位数分布及空间密度分布(3D结构)等结构信息。在水溶液中,Cl^-具有相对稳定的6水合结构,其水合距离为0.321 nm,外加阳离子对其水合作用的影响不明显。7.3 ± 1.4个水分子与Rb⁺水合,其特征水合距离为0.297 nm,8.4 ± 1.6个水分子与Cs⁺水合其水合距离为0.312 nm。Cs⁺不具有第二水合层,而Rb⁺表现出了更强的水合能力,具有较明显的第二水合层。Cl^-、Rb⁺及Cs⁺常被认为是“结构破坏”型离子。从微观角度来看这种所谓的“结构破坏”主要体现在破坏了本体水分子的第二水合层保持四面体构型的趋势。RbCl和CsCl水溶液中部分存在着Rb-Cl和Cs-Cl直接接触离子对,在1.0 mol·dm^-3的溶液中Rb-Cl及Cs-Cl的特征距离分别为0.324和0.336 nm,溶剂分割离子对的距离则都在0.6 nm左右。相对于Cs⁺,Rb⁺与Cl^-离子之间表现出了更强的缔合能力。     

风化壳淋积型稀土矿多级逆流浸取实验研究

风化壳淋积型稀土矿的开采主要通过浸矿剂离子与吸附在黏土矿物表面的稀土离子发生离子交换浸出反应实现。以(NH₄)₂SO₄为浸矿剂,采用多级逆流浸取的方式研究了风化壳淋积型稀土矿的浸矿过程,通过在逐级浸取过程中浸出液组分的变化分析了矿土中稀土离子(RE³⁺)和主要杂质铝离子(Al³⁺)的浸出行为,并基于浸矿剂的消耗规律探讨了浸矿剂离子与RE³⁺和Al³⁺的离子交换反应机制以及原矿土的净吸附量。结果表明,在浸矿液逐级浸取新鲜矿土的过程中,浸出液中的RE³⁺和Al³⁺浓度逐渐增加,铵根离子(NH₄⁺)逐渐消耗,交换进入浸出液中的RE³⁺和Al³⁺逐级减少;同时,浸出液中的硫酸根离子(SO₄^2-)逐级损耗,说明新鲜矿土除因发生离子交换反应消耗NH₄<...     

磷酸锡的离子交换性质(Ⅲ)——四十四种金属离子的薄层层析

本文用磷酸锡无机离子交换剂制成薄层板,不另加粘合剂,以DMSOHNO₃为混合溶剂系统对四十四种金属离子的薄层层析行为进行了研究。实验结果表明:在混合溶剂系统中,增加硝酸的浓度,磷酸锡交换剂中的交换基电离度降低,许多金属离子的比移值有所增加;当以DMSO-H₂(1:1)为溶剂,除Hg²⁺,Cd²⁺,Cr³⁺(或Cr⁶⁺和贵金属离子外,其它金属离子的比移位接近于零。故选择适当比例的DMSO-HNO₃和DMSO-H₂O为混合溶剂系统,利用磷酸锡对某些金属离子的选择性,可使许多金属离子相互分离。如:Hg²⁺与Pb²⁺,Cd²⁺与Pb²⁺,Hg²⁺与Hg₂²⁺,Pb²⁺与Zn²⁺,Hg²⁺与As³⁺等的分离是成功的。这些离子对环境保护中微量组分的分离和富集具有一定的使用价值。     

球形复合无机离子交换剂水合氧化钛-硅钛酸钠的制备及性能研究

用溶胶-凝胶法制备了球形除铯复合无机离子交换剂水合氧化钛-硅钛酸钠(HTO-NaTS),研究了在酸性条件下其对铯离子的交换性能,并对其结构、稳定性作了初步研究.结果表明,此种球形交换剂在强酸性条件下机械稳定性好,适合装柱,在1mol/L HNO3水溶液中,对铯离子具有较高的交换容量.     

Ultrafine Na-4-mica: uptake of alkali and alkaline earth metal cations by ion exchange

The cation exchange properties of alkali and alkaline earth metal cations at room temperature were investigated on an ultrafine, highly charged Na-4-mica (with the ideal mica composition Na4Mg6Al4Si4O20F4.xH2O). Ultrafine mica crystallites of 200 nm in size led to faster Sr2+ uptake kinetics in comparison to larger mica crystallites. The alkali metal ion (K+, Cs+, and Li+) exchange uptake was rapid, and complete exchange occurred within 30 min. For the alkaline earth metal ions Ba2+, Ca2+, and Mg2+, however, the exchange uptake required lengthy periods from 3 days to 4 weeks to be completed, similar to its Sr uptake, as previously reported. Kinetic models of the modified Freundlich and parabolic diffusion were examined for the experimental data on the Ba2+, Ca2+, and Mg2+ uptakes. The modified Freundlich model described well the Ba2+ ion uptake kinetics as well as that for the Sr2+ ion, while for the Ca2+ and Mg2+ ions the parabolic diffusion model showed better fitting. The alkali and alkaline earth ion exchange isotherms were also determined in comparison to the Sr2+ exchange isotherm. The thermodynamic equilibria for these cations were compared by using Kielland plots evaluated from the isotherms.     

Role of the hydroxyl-water hydrogen-bond network in structural transitions and selectivity toward cesium in Cs0.38(D1.08H0.54)SiTi2O7.(D0.86H0.14)2O crystalline silicotitanate

The crystal structure of the selective Cs+ ion exchanger D1.6H0.4Ti2SiO7.D2.66H0.34O1.5, known as crystalline silicotitanate or CST, has been determined in both native (D-CST) and in the Cs+-exchanged forms ((Cs, D)-CST) from angle-dispersive and time-of-flight neutron diffraction studies. The final fully exchange Cs+ form transformed from D-CST with unit cell parameters a = 11.0704(3) A c = 11.8917(5) A and space group P42/mbc, to one with a = 7.8902(1) A c = 11.9051(4) A and space group P42/mcm. Rietveld structure refinements of both D-CST and (Cs, D)-CST suggest the transition, and ultimately the selectivity, is driven by changes in the positions of water molecules, in response to the initial introduction of Cs+. The changes in water position appear to disrupt the D-O-O-D dihedral associated with the CST framework in space group P42/mbc which ultimately leads to the structural transition. The new geometric arrangement of the water-deuteroxyl network in (Cs, D)-CST suggests that Dwater-Ddeuteroxyl repulsion forced by Cs+ exchange drives the structural transformation.     

Gas phase hydrogen deuterium exchange reactions of a model peptide: FT-ICR and computational analyses of metal induced conformational mutations

We utilized gas phase hydrogen/deuterium (H/D) exchange reactions and ab initio calculations to investigate the complexation between a model peptide (Arg-Gly-AspRGD) with various alkali metal ions. The peptide conformation is drastically altered upon alkali metal ion complexation. The associated conformational changes depend on both the number and type of complexing alkali metal ions. Sodium has a smaller ionic diameter and prefers a multidentate interaction that involves all three amino acids of the peptide. Conversely, potassium and cesium form different types of complexes with the RGD. The [RGD + 2Cs − H]⁺ species exhibit the slowest H/D exchange reactivity (reaction rate constant of 6 × 10⁻¹³ cm³molecule⁻¹s⁻¹ for the fastest exchanging labile hydrogen with ND₃). The reaction rate constant of the protonated RGD is two orders of magnitude faster than that of the [RGD + 2Cs − H]⁺. Addition of the first cesium to the RGD reduces the H/D exchange reaction rate constant (i.e., D₀) by a factor of seven whereas sodium reduces this value by a factor of thirty. Conversely, addition of the second alkali metal ions has the opposite effect; the rate of D₀ disappearance for all [RGD + 2Met − H]⁺ species (MetNa, K, and Cs) decreases with the alkali metal ion size.     

Ion exchange in reverse micelles

The distribution and dynamics of alkali cations inside Na-AOT reverse micelles have been investigated using Monte Carlo and molecular dynamics simulations. Water is modeled using the extended simple point charge (SPC/E) model. Simulations were carried out for alkali salts of Li+, Na+, K+, and Cs+ placed into the aqueous core of the reverse micelle, for situations corresponding to one and three molecules of added salt. In all cases, we observe that the larger K+ and Cs+ ions exchange with the Na+ counterion; however, the smaller Li+ ion prefers to remains solvated within the core of the reverse micelle. Our study reveals that the oil-water interface of the Na-AOT reverse micelle has the greatest selectivity toward Cs+ followed by K+ and Li+. A model based on enthalpic contributions illustrates that the solvation energies of the different cations in water control the ion-exchange process. The hydration number of the first water shell for Li+ situated in the aqueous core of the reverse micelle with radius R = 14.1 A was similar to that observed at infinite dilution in bulk water.     

Gibbs energies of transfer of alkali metal cations between mutually saturated water-solvent systems determined from extraction experiments with radiotracer 137Cs

Thermodynamic standard Gibbs energies of transfer of alkali metal cations related to Cs+ cation [DeltatG degrees*,(Cs+)-[DeltatG degrees*,(M+)] between several mutually saturated solvents of the type water-solvent were calculated from determined extraction exchange constants Kexch degrees,*(Cs+/M+). The used liquid-liquid extraction method with radioactive tracing by 137Cs permits attaining higher precision of the values as compared to the methods used up to now. The data for o-nitrophenyloctyl ether, 1,2-dichloroethane, and 1-octanol were compared with literature sources and recommended absolute values of DeltatG degrees,*M+) are reported. For dissociating solvents, the dependences of [DeltatG degrees,*(Cs+) - [DeltatG degrees,*(M+)] on Gibbs energy of hydration of an ion, DeltaGhydr degrees are straight lines either for four cations Cs+, Rb+, K+, and Na+ (nitrosolvents) or for three cations Cs+, Rb+, and K+ (1,2-dichloroethane and 1-octanol). The hydration of Na+ and still more of Li+ in the water-saturated organic phase is apparent from the results. This manifests for high-water-content equilibrium 1-octanol even in a reversal of the values [i.e., DeltatG degrees*,(Li+) being more negative than DeltatG degrees,*(Na+)], although for Cs+, Rb+, and K+, the general trend is conserved. Water-saturated 1-octanol is thus slightly less basic than water, but the overall selectivity is very low. For one studied nondissociating solvent, dioctyl sebacate, the trend of the dependences of log Kexch degrees,*(CsB/M+) on DeltaGhydr degrees is similar to that of Kexch degrees,*(Cs+/M+) for polar solvents, but different for different anions B, thus reflecting ion association in the organic phase.     

多孔离子交换树脂内Eu3+离子的分步扩散

用同位素交换法研究了Eu³⁺离子在D72和D751树脂内的扩散过程.应用分步孔道扩散方程将粒内有效扩散系数D_e分解为孔道扩散系数D_p和固相扩散系数D_g,表明该方程可用于描述多孔树脂内的动力学过程.实验表明,D_e、D_p、D_g均随反应温度的升高而增大.计算了实验条件下的Eu³⁺的自扩散活化能;D72树脂的D_p和D_g对温度的响应比D751树脂大,其D_e、D_p、D_g值亦均大于D751树脂;Eu³⁺在溶液中的自扩散系数D_s＞D_p,说明离子在树脂孔道内的自扩散不能完全等同于其在溶液中的自扩散.     

Poly(ethylene glycol) doubly and singly cationized by different alkali metal ions: Relative cation affinities and cation-dependent resolution in a quadrupole ion trap mass spectrometer

Structural information of gas phase complexes of poly(ethylene glycol) (PEG) cationized by one or two different alkali metal ions is inferred from MS and MS/MS experiments performed with an electrospray quadrupole ion trap mass spectrometer. The rationale for selecting PEG was that its sites for cation binding are non-selective with respect to the repeating monomeric unit of the polymer, but there is selectivity with respect to the formation of an inner coordination sphere specific to each metal ion. The dissociation of [M1+ M2+ (EO23)], where EO23 = linear polymer of ethylene oxide, 23 units in length, resulted in loss of one of the alkali metal ions, with preference for loss of the larger cation, with no fragmentation of the PEG backbone for Na, K, Rb, and Cs. Li was not examined in this portion of the study. The selectivity for loss of the larger alkali metal ion was [Na+ K+ (EO23)] to [Na+ (EO23)] + K+ at 100%; [K+ Rb+ (EO23)] to [K+ (EO23)] + Rb+ at 93%; and [Rb+ Cs+ (EO23)] to [Rb+ (Eo23)] + Cs+ at 99%. The resolution of [M+ (EOx)] for x = 20-30 was dependent on the alkali metal ion, with the highest resolution observed for Cs+ and the lowest for Na+. These results are discussed with respect to the packing of the oxygen atoms on PEG (M.W.(avg) = 1000) around an alkali metal ion of different radius, and how this packing leads to an ensemble of unique structures, and therefore mobilities for [M+ (EOx)].     

有孔虫中硼的分离及其正热电离质谱法测定

针对大洋钻探计划(0DP)钻孔中有孔虫数量少、硼含量低的特点，改进了硼特效树脂和阴、阳混合离子交换树脂相结合进行分离硼的方法，成功地实现了硼的分离，并且首次采用正热电离质语法测定了有孔虫中硼同位素的比值。由于硼的分离过程不产生同位素分馏，测定结果令人满意。