The present invention relates to a new compound, a method for synthesizing the new compound, and an element separating and recovering agent. The new compound is made up of a coordination polymer that contains highly-ordered pores whose size is finely tunable.
Radioactive elements, such as strontium and cesium, are known to be typically separable by materials with pores, such as zeolites and Prussian blue, as is disclosed in JP 2016-80486 A and JP 2016-70781 A. Also, in general, water contaminated with radioactive materials, namely radioactive waste solutions, is subjected to a treatment process in which, for example, the radioactive elements are adsorbed by granular zeolites to lower the contamination level before being released to the sea or the like.
Unfortunately, however, it is very difficult for microporous materials such as zeolites and Prussian blue to efficiently separate and recover only a specific element from waste solutions (radioactive waste solutions, general industrial effluents, etc.) due to their extremely rigid structures and constant pore sizes. In addition, it is particularly difficult to take out the elements separated from waste solutions from such microporous materials, which prevents recycling of the separated elements.
And there is another problem. Take zeolites, for example, which have been conventionally used for this purpose. Used zeolites, which have taken up cesium, are radioactive wastes themselves, resulting in an increased amount of radioactive wastes.
In view of the above problems in the conventional art, the present invention has an object to provide a new compound with pores finely tunable in size so as to take up a specific element and release the specific element taken up in the pores as necessary, a method for synthesizing the new compound, and an element separating and recovering agent.
According to an aspect of the present invention, a new compound is represented by the following formula:
(NH4)[Ln(C2O4)2(H2O)]
wherein Ln is Sm, Eu, Tb, Dy, Ho, Er, Tm, Yb, or Lu.
By appropriately selecting the lanthanide metal (Ln), the amount of lanthanide contraction can be easily controlled. As a result, the new compound above is capable of efficiently separating and recovering a specific element from waste solutions as described above, for example. Therefore, the new compound finds an application as an element separating and recovering agent for separating and recovering a specific element.
(1) Specifically, the element separating and recovering agent to be used for the above purpose is made up of a coordination polymer. The coordination polymer has a structure with pores that are finely tunable in size by 0.1 Å or smaller through selection of the ions to be used for synthesis of the coordination polymer. Such a fine pore size tuning has never been possible with conventional materials. This fine pore size tuning makes it possible to change the pore size according to a specific purpose, namely to separate specific metal ions from a particular environment. Therefore, it is possible to obtain an ion separation agent that is best suited to a specific situation, for example, where small ions need to be removed from relatively large ions. As a result, it is now possible to separate strontium from seawater, which would be quite difficult with ordinary zeolites, for example, by tuning the pore size of this coordination polymer to meet the specific purpose.
(2) Since the coordination polymer has a structure that is more flexible in responding to the change of a solution than those of zeolites and Prussian blue, it is capable of releasing the ions it has taken up under an acidic condition at a pH value of around 4. This property makes it possible not only to separate a specific element into the element separating and recovering agent as effectively as conventional materials such as zeolites and Prussian blue, but also to recover the element. Isolation and recovery of radioactive cesium or strontium utilizing this method would open up the possibilities for use of radioisotopes as radiation sources and heat sources. Also, the used coordination polymer can be restored to its original state by subjecting it to a synthesis reaction, which means that waste is not produced, unlike the case with zeolites having adsorbed radioactive elements. Since this element separating and recovering agent is capable of separating and recovering radioactive elements from waste solutions or the like, it does not increase the amount of radioactive waste in large quantity, which is another advantage.
Also, according to another aspect of the present invention, the new compound described above is synthesized by a reaction expressed by the following formula:
wherein Ln is Sm, Eu, Tb, Dy, Ho, Er, Tm, Yb, or Lu.
Since its pores can be finely tuned in size to take up a specific element, with the new compound according to an embodiment of the present invention, when it is used as an element separating and recovering agent, separation of strontium from seawater, which is difficult with ordinary zeolites, is made possible by tuning the pore size of the coordination polymer that configures this element separating and recovering agent to meet the specific purpose.
Also, since it is capable of releasing as necessary the specific element that it has taken up into its pores, with the new compound according to an embodiment of the present invention, separation and isolation of radioactive cesium or strontium, for example, is made possible by using it as an element separating and recovering agent. Moreover, the used coordination polymer, namely element separating and recovering agent, can be restored to its original state by subjecting it to a synthesis reaction. This means that it does not produce extra waste, such as zeolites having adsorbed radioactive elements, or increase the amount of radioactive waste in large quantity.
First, a method for synthesizing a new compound that can be used as an element separating and recovering agent will be described referring to
As shown in Formula 2 above, the new compound according to an embodiment of the present invention was obtained by first immersing dimethyl oxalate and terbium chloride hexahydrate in an ammonium chloride-containing aqueous solution. The solution was then subjected to heating at 130° C. for 24 hours and filtering to separate colorless block-like crystals, which were cleansed.
Next, how to recover a specific metal selectively by using the synthesized new compound as an element separating and recovering agent will be described referring to
In other words, only the ions with a size that matches the size of the pore size can be separated. Actually, the difference in radius size among elements is extremely minute, so it would be difficult to recognize only specific metal ions by changing the pore size by 0.1 Å or larger. In the present invention, in order to recognize this minute difference in ionic radius, the pore size of the coordination polymer can be finely tuned by 0.1 Å or smaller by using lanthanide ions, which exhibit slight variation in ionic radius, as a component of the coordination polymer, to separate only specific ions.
As an exemplary result, separation of strontium from seawater, which would be difficult with conventional zeolites, is made possible by tuning the pore size of this coordination polymer to meet the specific purpose. Also, based on this finding, it is now possible to select an ion separation agent that is best suited to a specific situation, for example, where small ions need to be removed from relatively large ions.
Next, how to separate the recovered metal from the element separating and recovering agent will be described. By the scheme described below, the element is separated in a neutral state and then placed under an acidic condition to be separated and recovered from the coordination polymer. The coordination polymer itself becomes Ln2(C2O4)3, to which ligands and ammonium salt is added so that it is restored to the original coordination polymer, namely (NH4)[Ln(C2O4)2(H2O)], by a synthesis reaction. Through the series of treatments as described above, the original coordination polymer can be regenerated while separating and recovering the element.
The element separating and recovering agent (NH4)[Tb(C2O4)2(H2O)] as shown in
The results of strontium and barium uptake testing will be described referring to
20 mg of (NH4)[Tb(C2O4)2(H2O)] was added to a solution containing 162 ppm of strontium or 200 ppm of barium and stirred at 500 rpm for 10 minutes. The solution was then subjected to filtering, and the concentration of strontium or barium in the solution was measured to obtain the distribution constant (Kd) for strontium or barium. The results showed that the distribution constant for strontium and the distribution constant for barium of (NH4)[Tb(C2O4)2(H2O)] were 3.1×104 and 1.4×105 (ml/g), respectively. This distribution constant (Kd) for strontium was equivalent to those with zeolites, which are considered to be particularly effective in cleanup of strontium (see
The distribution constants (Kd) were obtained by the following formula:
wherein Ci represents the initial concentration of the ions in the solution (ppm), Ce represents the concentration of the ions in the solution at equilibrium (ppm), V represents the amount of the solution (2 ml), and M represents the amount of the element separating and recovering agent, (NH4)[Tb(C2O4)2(H2O)], as an adsorbent (0.02 g).
20 mg of (NH4)[Tb(C2O4)2(H2O)] was added to an artificial seawater Marine Art SF-1 (Osaka Yakken, Osaka, Japan, see the table of
20 mg of (NH4)[Ln(C2O4)2(H2O)] was added to a solution containing 20 ppm of strontium or 20 ppm of barium and stirred at 500 rpm for 10 minutes. The solution was then subjected to filtering, and the concentration of strontium or barium in the solution was measured to obtain the logarithm (log (Kd)) of the distribution constant with different metal elements. The results are shown in
For comparison between affinity for barium and affinity for strontium, the difference between the log for Ba, Log (Kd (Ba)), and the log for Strontium, Log (Kd (Sr)), for each metal is shown in
(1) 100 mg of (NH4)[Yb(C2O4)2(H2O)] was soaked in 10 ml of a cesium chloride solution (cesium concentration: 1,000 ppm) for four hours (298K, pH 7±1). It was observed that the cesium concentration in the solution had reduced by 61%. In this process, the powder X-ray pattern changed from a) to b) in
(NH4)[Yb(C2O4)2(H2O)]+CsCl→Cs[Yb(C2O4)2(H2O)]+NH4Cl [Formula 5]
(2) Next, the solution was filtered to obtain the powder, which was then suspended in 10 ml of pure water. To the obtained suspension, 0.001 ml of NHCl was added by an automatic titrator to keep its pH at 4, which allowed release of 95% of the cesium taken up in the polymer into the solvent. In this process, the powder X-ray pattern changed from b) to c) in
2(Cs[Yb(C2O4)2(H2O)])+HCl→Yb2(C2O4)3+2Cs++H(C2O4)−+Cl− [Formula 6]
(3) Next, the suspension was filtered to obtain the powder, or Yb2(C2O4)3. n(H2O), to which dimethyl oxalate and ammonium chloride were added, and the mixture was heated at 130° C. for 24 hours. As a result, the powder X-ray pattern changed from c) to d) in
Yb2(C2O4)3+(CH3)2(C2O4)+NH4Cl→(NH4)[Yb(C2O4)2(H2O)]+2CH3OH [Formula 7]
It was proved that through the reactions as described above, this coordination polymer is capable of taking up cesium, releasing the cesium that it has taken up, and being restored to the original coordination polymer after the release and the use.
Number | Date | Country | Kind |
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2016-161059 | Aug 2016 | JP | national |