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From “S” to “O”: experimental and theoretical insights into the atmospheric degradation mechanism of dithiophosphinic acids

Dithiophosphinic acids (DPAHs, expressed as R(1)R(2)PSSH) are a type of sulfur-donor ligand that have been vastly applied in hydrometallurgy. In particular, DPAHs have shown great potential in highly efficient trivalent actinide/lanthanide separation, which is one of the most challenging tasks in se...

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Autores principales: Wang, Zhipeng, Zhang, Yixiang, Liu, Jingjing, Song, Lianjun, Wang, Xueyu, Yang, Xiuying, Xu, Chao, Li, Jun, Ding, Songdong
Formato: Online Artículo Texto
Lenguaje:English
Publicado: The Royal Society of Chemistry 2020
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9057479/
https://www.ncbi.nlm.nih.gov/pubmed/35520876
http://dx.doi.org/10.1039/d0ra08841b
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author Wang, Zhipeng
Zhang, Yixiang
Liu, Jingjing
Song, Lianjun
Wang, Xueyu
Yang, Xiuying
Xu, Chao
Li, Jun
Ding, Songdong
author_facet Wang, Zhipeng
Zhang, Yixiang
Liu, Jingjing
Song, Lianjun
Wang, Xueyu
Yang, Xiuying
Xu, Chao
Li, Jun
Ding, Songdong
author_sort Wang, Zhipeng
collection PubMed
description Dithiophosphinic acids (DPAHs, expressed as R(1)R(2)PSSH) are a type of sulfur-donor ligand that have been vastly applied in hydrometallurgy. In particular, DPAHs have shown great potential in highly efficient trivalent actinide/lanthanide separation, which is one of the most challenging tasks in separation science and is of great importance for the development of an advanced fuel cycle in nuclear industry. However, DPAHs have been found liable to undergo oxidative degradation in the air, leading to significant reduction in the selectivity of actinide/lanthanide separation. In this work, the atmospheric degradation of five representative DPAH ligands was investigated for the first time over a sufficiently long period (180 days). The oxidative degradation process of DPAHs elucidated by ESI-MS, (31)P NMR, and FT-IR analyses is R(1)R(2)PSSH → R(1)R(2)PSOH → R(1)R(2)POOH → R(1)R(2)POO–OOPR(1)R(2), R(1)R(2)PSSH → R(1)R(2)PSS–SSPR(1)R(2), and R(1)R(2)PSSH → R(1)R(2)PSOH → R(1)R(2)POS–SOPR(1)R(2). Meanwhile, the determination of pK(a) values through pH titration and oxidation product by PXRD further confirms the S → O transformation in the process of DPAH deterioration. DFT calculations suggest that the hydroxyl radical plays the dominant role in the oxidation process of DPAHs and the order in which the oxidation products formed is closely related to the reaction energy barrier. Moreover, nickel salts of DPAHs have shown much higher chemical stability than DPAHs, which was also elaborated through molecular orbital (MO) and adaptive natural density portioning (AdNDP) analyses. This work unambiguously reveals the atmospheric degradation mechanism of DPAHs through both experimental and theoretical approaches. At the application level, the results not only provide an effective way to preserve DPAHs but could also guide the design of more stable sulfur-donor ligands in the future.
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spelling pubmed-90574792022-05-04 From “S” to “O”: experimental and theoretical insights into the atmospheric degradation mechanism of dithiophosphinic acids Wang, Zhipeng Zhang, Yixiang Liu, Jingjing Song, Lianjun Wang, Xueyu Yang, Xiuying Xu, Chao Li, Jun Ding, Songdong RSC Adv Chemistry Dithiophosphinic acids (DPAHs, expressed as R(1)R(2)PSSH) are a type of sulfur-donor ligand that have been vastly applied in hydrometallurgy. In particular, DPAHs have shown great potential in highly efficient trivalent actinide/lanthanide separation, which is one of the most challenging tasks in separation science and is of great importance for the development of an advanced fuel cycle in nuclear industry. However, DPAHs have been found liable to undergo oxidative degradation in the air, leading to significant reduction in the selectivity of actinide/lanthanide separation. In this work, the atmospheric degradation of five representative DPAH ligands was investigated for the first time over a sufficiently long period (180 days). The oxidative degradation process of DPAHs elucidated by ESI-MS, (31)P NMR, and FT-IR analyses is R(1)R(2)PSSH → R(1)R(2)PSOH → R(1)R(2)POOH → R(1)R(2)POO–OOPR(1)R(2), R(1)R(2)PSSH → R(1)R(2)PSS–SSPR(1)R(2), and R(1)R(2)PSSH → R(1)R(2)PSOH → R(1)R(2)POS–SOPR(1)R(2). Meanwhile, the determination of pK(a) values through pH titration and oxidation product by PXRD further confirms the S → O transformation in the process of DPAH deterioration. DFT calculations suggest that the hydroxyl radical plays the dominant role in the oxidation process of DPAHs and the order in which the oxidation products formed is closely related to the reaction energy barrier. Moreover, nickel salts of DPAHs have shown much higher chemical stability than DPAHs, which was also elaborated through molecular orbital (MO) and adaptive natural density portioning (AdNDP) analyses. This work unambiguously reveals the atmospheric degradation mechanism of DPAHs through both experimental and theoretical approaches. At the application level, the results not only provide an effective way to preserve DPAHs but could also guide the design of more stable sulfur-donor ligands in the future. The Royal Society of Chemistry 2020-11-04 /pmc/articles/PMC9057479/ /pubmed/35520876 http://dx.doi.org/10.1039/d0ra08841b Text en This journal is © The Royal Society of Chemistry https://creativecommons.org/licenses/by-nc/3.0/
spellingShingle Chemistry
Wang, Zhipeng
Zhang, Yixiang
Liu, Jingjing
Song, Lianjun
Wang, Xueyu
Yang, Xiuying
Xu, Chao
Li, Jun
Ding, Songdong
From “S” to “O”: experimental and theoretical insights into the atmospheric degradation mechanism of dithiophosphinic acids
title From “S” to “O”: experimental and theoretical insights into the atmospheric degradation mechanism of dithiophosphinic acids
title_full From “S” to “O”: experimental and theoretical insights into the atmospheric degradation mechanism of dithiophosphinic acids
title_fullStr From “S” to “O”: experimental and theoretical insights into the atmospheric degradation mechanism of dithiophosphinic acids
title_full_unstemmed From “S” to “O”: experimental and theoretical insights into the atmospheric degradation mechanism of dithiophosphinic acids
title_short From “S” to “O”: experimental and theoretical insights into the atmospheric degradation mechanism of dithiophosphinic acids
title_sort from “s” to “o”: experimental and theoretical insights into the atmospheric degradation mechanism of dithiophosphinic acids
topic Chemistry
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9057479/
https://www.ncbi.nlm.nih.gov/pubmed/35520876
http://dx.doi.org/10.1039/d0ra08841b
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