2020
DOI: 10.1002/ange.201916334
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Ligand‐Supported Facile Conversion of Uranyl(VI) into Uranium(IV) in Organic and Aqueous Media

Abstract: Reduction of uranyl(VI) to U V and to U IV is important in uranium environmental migration and remediation processes. The anaerobic reduction of a uranyl U VI complex supported by a picolinate ligand in both organic and aqueous media is presented. The [U VI O 2 (dpaea)] complex is readily converted into the cis-boroxide U IV species via diborane-mediated reductive functionalization in organic media. Remarkably, in aqueous media the uranyl(VI) complex is rapidly converted, by Na 2 S 2 O 4 , a reductant relevant… Show more

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Cited by 10 publications
(13 citation statements)
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“…Herein, in this system, DMSO acts a solvent as well as oxidant which oxidises the Co(II) to Co(III). Similar kind of role of DMSO has been previously reported by Wu et al [21] Co(II) donates an electron to the antibonding orbital of DMSO, as a result the oxidation state of the complex SN-1 changes from Co(II) to Co(III). Hence the formed complex becomes diamagnetic in nature.…”
Section: Chemodosimetric Validation Of Sn-1 Using Nmr Spectroscopysupporting
confidence: 82%
“…Herein, in this system, DMSO acts a solvent as well as oxidant which oxidises the Co(II) to Co(III). Similar kind of role of DMSO has been previously reported by Wu et al [21] Co(II) donates an electron to the antibonding orbital of DMSO, as a result the oxidation state of the complex SN-1 changes from Co(II) to Co(III). Hence the formed complex becomes diamagnetic in nature.…”
Section: Chemodosimetric Validation Of Sn-1 Using Nmr Spectroscopysupporting
confidence: 82%
“…The two goals of this work were to confirm that U­(V) forms as a pathway intermediate in the presence of complexing ligands such as dpaea and to establish whether U­(V)–dpaea undergoes further biological reduction to U­(IV). We note that direct reduction of the U­(V)–dpaea complex by chemical reagents has been recently observed by some of the authors in both organic solvents and in water affording monometallic ([U IV (dpaea)­(OBpin) 2 (py)] and trimetallic ([Na­(H 2 O) 5 {U­(dpaea)} 3 (μ-O) 2 (μ–OH)­(μ 3 -SO 3 )]) complexes, respectively . Previously reported complexes of dpaea with uranium include U­(VI)–dpaea ([UO 2 (dpaea)]), U­(V)–dpaea ([K­(2.2.2.crypt)]­[UO 2 (dpaea)]), U­(IV)–dpaea (U­(dpaea) 2 ) , and the trinuclear uranium­(IV) μ-oxo/hydroxo bridged cluster [Na­(H 2 O) 5 {U­(dpaea)} 3 (μ-O) 2 (μ–OH)­(μ 3 -SO 3 )] obtained from the chemical reduction of U­(VI)– and U­(V)–dpaea in water.…”
Section: Introductionmentioning
confidence: 55%
“…The MtrCAB protein complex in S. oneidensis MR-1 spans potentials from 0 to −400 mV (against the standard hydrogen electrode (SHE)), 48 and therefore accesses a large range of redox substrates. The reduction potential of U(VI)–dpaea/U(V)–dpaea was −312 mV (SHE), 37 thus, the first reduction step of U(VI) to U(V), lies within the reduction potentials accessible to the MtrCAB complex. It suggests that a one-electron reduction of U(VI)–dpaea by MtrC/OmcA would be energetically favorable.…”
Section: Resultsmentioning
confidence: 98%
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