Column Separation of Am(III) and Eu(III) by α-Zirconium Phosphate Ion Exchanger in Nitric Acid

被引：5

作者：

Wiikinkoski, Elmo W. ^{[1
]}

Rautsola, Iiro ^{[1
]}

Xu, Junhua ^{[1
]}

Koivula, Risto ^{[1
]}

机构：

[1] Univ Helsinki, Dept Chem Radiochem, AI Virtasen Aukio 1,POB 55, Helsinki 00014, Finland

来源：

CHEMENGINEERING | 2020年 / 4卷 / 01期

关键词：

ion exchange; column separation; nuclear fuel; lanthanides; actinides; zirconium phosphate; THERMODYNAMICS; MECHANISM;

D O I：

10.3390/chemengineering4010014

中图分类号：

TQ [化学工业];

学科分类号：

0817 ;

摘要：

The trivalent lanthanide-actinide separations are a major challenge in reprocessing of nuclear fuels. To achieve this, commonly organic extractants and solvents are utilized in elaborate processes. Here we report a simple new method that can perform a supportive or alternative role. A nanocrystalline alpha -zirconium phosphate ion exchanger was utilized for Eu(III)/Am(III) column separation. Comprehensive preliminary studies were done using batch experiments to optimize the final separation conditions. The distribution coefficients for Eu were determined as a function of pH (from 0 to 3) and salinity (Na, Sr). The distribution coefficients for Am were determined as a function of pH, and Eu concentration, from 1:40 to 10,000:1 Eu:Am molar ratio. The exchanger always preferred Eu over Am in our experimental conditions. Separation factors (Eu:Am) of up to 400 were achieved in binary Eu-Am solution in pH 1. The breakthrough capacity was determined in dynamic column conditions using Eu: 0.3 meq.g(-1), which is approximately 4% of the theoretical maximum capacity. Two types of hot column separation tests were conducted: (i) binary load (selective Am elution), and (ii) continuous equimolar binary feed. In both cases separation was achieved. In (i), the majority (82% of the recovered 93%) of Am could be purified from Eu with extremely high 99.999% molar purity, while alternatively even more (95% of the recovered 93%) at a lower purity of 99.7 mol %. In (ii), up to 330 L.kg(-1) of the equimolar solution per mass of the exchanger could be treated with Am purity above 99.5 mol % in the total eluate. Alternatively, up to 630 L.kg(-1) above 95 mol %, or up to 800 L.kg(-1) above 90 mol % purities.

引用

页码：1 / 13

页数：13

共 23 条

[1] RECENT PROGRESS IN FIELD OF SYNTHETIC INORGANIC EXCHANGERS HAVING A LAYERED OR FIBROUS STRUCTURE [J].

ALBERTI, G ;

COSTANTINO, U .

JOURNAL OF CHROMATOGRAPHY, 1974, 102 (DEC31) :5-29

[2] STOICHEIOMETRY OF ION EXCHANGE MATERIALS CONTAINING ZIRCONIUM AND PHOSPHATE [J].

ALBERTI, G ;

TORRACCA, E ;

CONTE, A .

JOURNAL OF INORGANIC & NUCLEAR CHEMISTRY, 1966, 28 (02) :607-&

[3] ON MECHANISM OF ION EXCHANGE IN CRYSTALLINE ZIRCONIUM PHOSPHATES .I. SODIUM ION EXCHANGE OF ALPHA-ZIRCONIUM PHOSPHATE [J].

CLEARFIE.A ;

DUAX, WL ;

MEDINA, AS ;

SMITH, GD ;

THOMAS, JR .

JOURNAL OF PHYSICAL CHEMISTRY, 1969, 73 (10) :3424-&

[4] INORGANIC-ION EXCHANGERS WITH LAYERED STRUCTURES [J].

CLEARFIELD, A .

ANNUAL REVIEW OF MATERIALS SCIENCE, 1984, 14 :205-229

[5] ZIRCONIUM AND TITANIUM PHOSPHATES AS CATALYSTS - A REVIEW [J].

CLEARFIELD, A ;

THAKUR, DS .

APPLIED CATALYSIS, 1986, 26 (1-2) :1-26

[6] CRYSTALLOGRAPHY AND STRUCTURE OF ALPHA-ZIRCONIUM BIS(MONOHYDROGEN ORTHOPHOSPHATE) MONOHYDRATE [J].

CLEARFIELD, A ;

SMITH, GD .

INORGANIC CHEMISTRY, 1969, 8 (03) :431-+

[7] THE PREPARATION OF CRYSTALLINE ZIRCONIUM PHOSPHATE AND SOME OBSERVATIONS ON ITS ION EXCHANGE BEHAVIOUR [J].

CLEARFIELD, A ;

STYNES, JA .

JOURNAL OF INORGANIC & NUCLEAR CHEMISTRY, 1964, 26 (01) :117-129

[8]

Colon J.L., 2015, TAILORED ORGANIC INO

[9] ION EXCHANGE PROPERTIES OF CRYSTALLINE ZIRCONIUM PHOSPHATE [J].

HARVIE, SJ ;

NANCOLLA.GH .

JOURNAL OF INORGANIC & NUCLEAR CHEMISTRY, 1970, 32 (12) :3923-&

[10] MECHANISM OF ION-EXCHANGE IN ZIRCONIUM-PHOSPHATES .32. THERMODYNAMICS OF ALKALI-METAL ION-EXCHANGE ON CRYSTALLINE ALPHA-ZRP [J].

KULLBERG, L ;

CLEARFIELD, A .

JOURNAL OF PHYSICAL CHEMISTRY, 1981, 85 (11) :1585-1589

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