Conditioning of Spent Electrolyte Surrogate LiCl-KCl-CsCl Using Magnesium Potassium Phosphate Compound

Kulikova, Svetlana A.; Belova, Kseniya Y.; Tyupina, E. A.; Винокуров, С. Е.

doi:10.3390/en13081963

Cited by 14 publications

(6 citation statements)

References 29 publications

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“…It was shown that lithium and cesium are present in the compound as components of low-soluble phosphates, for example, cesium-MgCsPO 4 •6H 2 O (Phase #4, main reflexes at 5.40 and 3.44 Å), indicating the replacement of potassium ions with cesium in the matrix structure, while lithium-Li 3 PO 4 (Phase #5, lithiophosphate, main reflexes at 3.99 and 3.82 Å). This is confirmed by the presence of the KCl phase (Phase #6, sylvite, main reflexes at 3.15 and 2.23 Å) in the compound, which was also noted earlier in the immobilization of CsCl in the MPP compound [18].…”

Section: Characterization Of the Synthesised Compounds Containing Chl...supporting

confidence: 83%

“…Earlier [21], it was shown that heat treatment at a temperature of ≥300 • C resulted in thermal decomposition of the formed FKCN. Thus, the thermal stability of the MPP compound was studied at 270 • C for 4 h. The samples of the MPP compound were preliminarily kept at 180 • C for 10 h for removal of bound water from MgKPO 4 •6H 2 O-based compounds in a muffle furnace SNOL 30/1300 (AB UMEGA GROUP, Utena, Lithuania), as previously shown in [18].…”

Section: Methodsmentioning

confidence: 99%

“…At present, a magnesium potassium phosphate (MPP) matrix, obtained at room temperature and being a synthetic analogue of the natural mineral K-struvite, is considered as an alternative to glass for HLW immobilization. The MPP matrix is an effective mineral-like material with high hydrolytic, mechanical and radiation resistance, as shown earlier in [18][19][20]. Therefore, these materials were chosen for the immobilization of the spent electrolyte.…”

Section: Introductionmentioning

confidence: 99%

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Perspective Compounds for Immobilization of Spent Electrolyte from Pyrochemical Processing of Spent Nuclear Fuel

et al. 2021

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Immobilization of spent electrolyte–radioactive waste (RW) generated during the pyrochemical processing of mixed nitride uranium–plutonium spent nuclear fuel is an acute task for further development of the closed nuclear fuel cycle with fast neutron reactors. The electrolyte is a mixture of chloride salts that cannot be immobilized directly in conventional cement or glass matrix. In this work, a low-temperature magnesium potassium phosphate (MPP) matrix and two types of high-temperature matrices (sodium aluminoironphosphate (NAFP) glass and ceramics based on bentonite clay) were synthesized. Two systems (Li0.4K0.28La0.08Cs0.016Sr0.016Ba0.016Cl and Li0.56K0.40Cs0.02Sr0.02Cl) were used as spent electrolyte imitators. The phase composition and structure of obtained materials were studied by XRD and SEM-EDS methods. The differential leaching rate of Cs from MPP compound and ceramic based on bentonite clay was about 10−5 g/(cm2·day), and the rate of Na from NAFP glass was about 10−6 g/(cm2·day). The rate of 239Pu from MPP compound (leaching at 25 °C) and NAFP glass (leaching at 90 °C) was about 10−6 and 10−7 g/(cm2·day), respectively. All the synthesized materials demonstrated high hydrolytic, mechanical compression strength (40–50 MPa) even after thermal (up to 450 °C) and irradiation (up to 109 Gy) tests. The characteristics of the studied matrices correspond to the current requirements to immobilized high-level RW, that allow us to suggest these materials for industrial processing of the spent electrolyte.

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Section: Characterization Of the Synthesised Compounds Containing Chl...supporting

confidence: 83%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Perspective Compounds for Immobilization of Spent Electrolyte from Pyrochemical Processing of Spent Nuclear Fuel

et al. 2021

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“…This indicates that the use of synthetic analogs of minerals as matrices for immobilization of radioactive waste is promising. Breakthrough results in recent years [29][30][31] were obtained in the study of the possibility of using crystalline double orthophosphate of magnesium and potassium (MPP) as synthetic matrices for long-term and environmentally safe storage (or disposal) of liquid radioactive waste, including actinide-containing waste. The synthesis of the MPP matrix occurs in an aqueous solution according to the reaction The nonthermal process (room temperature, atmospheric pressure) of obtaining MPP matrices is similar to cementing and is characterized by low energy consumption, ease of implementation, and mobility of the curing process, and the simplicity of the hardware design of the method leads to minimization of "secondary" radioactive waste.…”

Section: New Safe Matrices For Radioactive Waste Immobilizationmentioning

confidence: 99%

Chemical Technologies for Closing the Nuclear Fuel Cycle

Myasoedov

Калмыков

Shadrin

2021

Her. Russ. Acad. Sci.

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Nuclear power is a highly concentrated energy source that does not emit greenhouse gases and does not affect the climate. In the future, it should hold a significant share in the world energy balance, but this possibility is realized only if the technological problems of closing the nuclear fuel cycle like minimizing the radioactive waste generated and multi-recycling of fissile isotopes are solved. This will make it possible to solve both ecological and economic problems, moving away from deep disposal of long-lived radionuclides to their transmutation, followed by near-surface disposal of short-lived radionuclides.

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“…Previously, in a number of literary sources [2][3][4][5][6][7][8][9][10][11][12][13], it was shown that the compound based on the magnesium potassium phosphate (MPP) matrix MgKPO 4 × 6H 2 O, which is formed at room temperature and is an analogue of the natural mineral K-struvite [14], is a promising material for immobilization of various LRW types, including HLW. A key task during HLW immobilization is to ensure binding of mobile cesium isotopes in the MPP compound.…”

Section: Introductionmentioning

confidence: 99%

Optimization of the Solidification Method of High-Level Waste for Increasing the Thermal Stability of the Magnesium Potassium Phosphate Compound

et al. 2020

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The key task in the solidification of high-level waste (HLW) into a magnesium potassium phosphate (MPP) compound is the immobilization of mobile cesium isotopes, the activity of which provides the main contribution to the total HLW activity. In addition, the obtained compound containing heat-generating radionuclides can be significantly heated, which increases the necessity of its thermal stability. The current work is aimed at assessing the impact of various methodological approaches to HLW solidification on the thermal stability of the MPP compound, which is evaluated by the mechanical strength of the compound and its resistance to cesium leaching. High-salt surrogate HLW solution (S-HLW) used in the investigation was prepared for solidification by adding sorbents of various types binding at least 93% of 137Cs: ferrocyanide K-Ni (FKN), natural zeolite (NZ), synthetic zeolite Na-mordenite (MOR), and silicotungstic acid (STA). Prepared S-HLW was solidified into the MPP compound. Wollastonite (W) and NZ as fillers were added to the compound composition in the case of using FKN and STA, respectively. It was found that heat treatment up to 450 °C of the compound containing FKN and W (MPP-FKN-W) almost did not affect its compressive strength (about 12–19 МPa), and it led to a decrease of high compressive strength (40–50 MPa) of the compounds containing NZ, MOR, and STA (MPP-NZ, MPP-MOR, and MPP-STA-NZ, respectively) by an average of 2–3 times. It was shown that the differential leaching rate of 137Cs on the 28th day from MPP-FKN-W after heating to 250 °C was 5.3 × 10−6 g/(cm2∙day), however, at a higher temperature, it increased by 20 and more times. The differential leaching rate of 137Cs from MPP-NZ, MPP-MOR, and MPP-STA-NZ had values of (2.9–11) × 10−5 g/(cm2∙day), while the dependence on the heat treatment temperature of the compound was negligible.

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Conditioning of Spent Electrolyte Surrogate LiCl-KCl-CsCl Using Magnesium Potassium Phosphate Compound

Cited by 14 publications

References 29 publications

Perspective Compounds for Immobilization of Spent Electrolyte from Pyrochemical Processing of Spent Nuclear Fuel

Perspective Compounds for Immobilization of Spent Electrolyte from Pyrochemical Processing of Spent Nuclear Fuel

Chemical Technologies for Closing the Nuclear Fuel Cycle

Optimization of the Solidification Method of High-Level Waste for Increasing the Thermal Stability of the Magnesium Potassium Phosphate Compound

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