Andrea N. Alsobrook scite author profile

The hydrothermal reaction of phosphonoacetic acid (H2PO3CH2C(O)OH, PAA) with UO3 and Cu(C2H3O2)2 .H2O results in the formation of the crystalline heterobimetallic uranium(VI)/copper(II) phosphonates UO2Cu(PO3CH2CO2)(OH)(H2O)2 ( UCuPAA-1), (UO2) 2Cu(PO3CH2CO2)2(H2O)3 (UCuPAA-2), and [H3O][(UO2) 2Cu2(PO3CH2CO2)3(H2O)2 ( UCuPAA-3). The addition of sodium hydroxide to the aforementioned reactions results in the formation of Na[UO2(PO3CH2CO2)].2H2O (NaUPAA-1). These compounds display 1D (UCuPAA-1), 2D (UCuPAA-2, NaUPAA-1), and 3D (UCuPAA-3) architectures wherein the phosphonate portion of the ligand primarily coordinates the uranium(VI) centers; whereas the carboxylate moiety preferentially, but not exclusively, binds to the copper(II) ions. Fluorescence measurements on all four compounds demonstrate that the presence of copper(II) mostly quenches the emission from the uranyl moieties.

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Cubic and rhombohedral heterobimetallic networks constructed from uranium, transition metals, and phosphonoacetate: new methods for constructing porous materials

Alsobrook

et al. 2010

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Four heterobimetallic U(vi)/M(ii) (M = Mn, Co, Cd) carboxyphosphonates have been synthesized. M(2)[(UO(2))(6)(PO(3)CH(2)CO(2))(3)O(3)(OH)(H(2)O)(2)]·16H(2)O (M = Mn(ii), Co(ii), and Cd(ii)) adopt cubic three-dimensional network structures with large cavities approximately 16 Å in diameter that are filled with co-crystallized water molecules. [Cd(3)(UO(2))(6)(PO(3)CH(2)CO(2))(6)(H(2)O)(13)]·6H(2)O forms a rhombohedral channel structure with hydrated Cd(ii) within the channels. The cubic compound (Co) displays differential gas absorption with a surface area for CO(2) uptake of 40 m(2) g(-1) at 273 K, and no uptake of N(2) at 77 K.

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From Layered Structures to Cubic Frameworks: Expanding the Structural Diversity of Uranyl Carboxyphosphonates via the Incorporation of Cobalt

Alsobrook

Hauser

Hupp

et al. 2011

Crystal Growth & Design

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Five heterobimetallic U(VI)/Co(II) carboxyphosphonates have been synthesized under mild hydrothermal conditions by reacting UO 3 , Co(CH 3 CO 2) 2 3 4H 2 O, and triethyl phosphonoacetate. These compounds, Co(H 2 O) 4 [(UO 2) 2 (PO 3-CH 2 CO 2) 2 (H 2 O) 2 ] (CoUPAA-1), [Co(H 2 O) 6 ][UO 2 (PO 3 CH 2 CO 2)] 2 3 8H 2 O (CoUPAA-2), Co(H 2 O) 4 [UO 2 (PO 3 CH 2 CO 2)] 2 3 4H 2 O (CoUPAA-3), Co(H 2 O) 4 [(UO 2) 6 (PO 3 CH 2 CO 2) 2 O 2 (OH) 3 (H 2 O) 3 ] 2 3 3H 2 O (CoUPAA-4), and Co 2 [(UO 2) 6 (PO 3 CH 2-CO 2) 3 O 3 (OH)(H 2 O) 2 ] 3 16H 2 O (CoUPAA-5), range from two-to three-dimensional structures. CoUPAA-1 to CoUPAA-3 all possess uranyl carboxyphosphonate layers that are separated by the Co(II) cation with varying degrees of hydration. CoUPAA-4 contains both UO 7 pentagonal bipyramids and UO 8 hexagonal bipyramids within the uranyl carboxyphosphonate plane. Unlike the first four low-symmetry compounds, CoUPAA-5 is a cubic, three-dimensional network with large cavities approximately 16 Å in diameter that are filled with cocrystallized water molecules. Differential gas absorption measurements performed on CoUPAA-5 displayed a surface area uptake for CO 2 of 40 m 2 g-1 at 273 K, and no uptake for N 2 at 77 K.

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Phosphonoacetate as a Ligand for Constructing Layered and Framework Alkali Metal Uranyl Compounds

Alsobrook

Albrecht‐Schmitt

2009

Inorg. Chem.

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The hydrothermal reactions of KCl, RbCl, CsOH, and CsCl with phosphonoacetic acid and uranium trioxide at 180 degrees C for three to five days results in the formation of five different crystalline uranyl carboxyphosphonates, K[(UO(2))(2)(PO(3)CH(2)CO(2))(PO(3)CH(2)CO(2)H)(H(2)O)] x H(2)O, Rb[(UO(2))(2)(PO(3)CH(2)CO(2))(PO(3)CH(2)CO(2)H)(H(2)O)] x H(2)O, Cs[(UO(2))(2)(PO(3)CH(2)CO(2))(PO(3)CH(2)CO(2)H)(H(2)O)] x H(2)O, Cs[(UO(2))(PO(3)CH(2)CO(2))], and Cs(3)[(UO(2))(4)(PO(3)CH(2)O(2))(2)(PO(3)CH(2)CO(2)H(0.5))(2)] x nH(2)O, respectively. In all compounds, the UO(2)(2+) moieties are bound by phosphonate and carboxylate forming pentagonal bipyramidal environments around the uranium centers. At low pH, some of the carboxylate portions of the phosphonoacetate are protonated. The addition of hydroxide removes these protons, and a different structure is adopted. In contrast to all other uranyl carboxyphosphonates, Cs(3)[(UO(2))(4)(PO(3)CH(2)O(2))(2)(PO(3)CH(2)CO(2)H(0.5))(2)] x nH(2)O adopts a three-dimensional network structure with large channels along the c axis that house the Cs(+) cations.

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Incorporation of Mn(II) and Fe(II) into Uranyl Carboxyphosphonates

Alsobrook

Alekseev

Depmeier

et al. 2011

Crystal Growth & Design

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Five heterobimetallic U(VI)/M(II) (M = Mn, Fe) carboxyphosphonates have been synthesized under mild hydrothermal conditions by reacting UO3, triethyl phosphonoacetate, with either Mn(II) or Fe(II) acetate. The manganese reactions yield Mn2[(UO2)6(PO3CH2CO2)3O3(OH)(H2O)2]·16H2O (MnUPAA-1) and [Mn(H2O)6][Mn(H2O)5Mn2(UO2)5(PO3CH2CO2)6(H2O)]·5.75H2O (MnUPAA-2). The addition of boric acid, which lowers the crystallization temperature, allows for the production of a third product, [Mn(H2O)4]2(UO2)3(PO3CH2CO2)2O2 (MnUPAA-3). The iron-containing reactions yield [Fe(H2O)6][UO2(PO3CH2CO2)]2·8H2O (FeUPAA-1) and [Fe(H2O)6][UO2(PO3CH2CO2)H2O]2·4H2O (FeUPAA-2). Four of these five compounds crystallize in low-symmetry space groups; whereas MnUPAA-1 crystallizes in the cubic space group Im3̅ and possesses a remarkably complex open-framework structure containing both UO7 pentagonal bipyramids and UO8 hexagonal bipyramids. MnUPAA-3 adopts a one-dimensional uranium oxide topology that contains both UO6 tetragonal bipyramids and UO7 pentagonal bipyramids. The remaining three compounds solely contain UO7 pentagonal bipyramids.

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Uranyl carboxyphosphonates that incorporate Cd(II)

Alsobrook¹,

Alekseev²,

Depmeier³

et al. 2011

Journal of Solid State Chemistry

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Ion Exchange Performance of Titanosilicates, Germanates and Carbon Nanotubes

Alsobrook¹,

Hobbs²

2013

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This report presents a summary of testing the affinity of titanosilicates (TSP), germaniumsubstituted titanosilicates (Ge-TSP) and multiwall carbon nanotubes (MWCNT) for lanthanide ions in dilute nitric acid solution. The K-TSP ion exchanger exhibited the highest affinity for lanthanides in dilute nitric acid solutions. The Ge-TSP ion exchanger shows promise as a material with high affinity, but additional tests are needed to confirm the preliminary results. The MWCNT exhibited much lower affinities than the K-TSP in dilute nitric acid solutions. However, the MWCNT are much more chemically stable to concentrated nitric acid solutions and, therefore, may candidates for ion exchange in more concentrated nitric acid solutions.This technical report serves as the deliverable documenting completion of the FY13 research milestone, M4FT-13SR0303061 -measure actinide and lanthanide distribution values in nitric acid solutions with sodium and potassium titanosilicate materials. Ion Exchange Performance 5 ACRONYMS CST crystalline silicotitanate Ge-TSP germanium-substituted titanosilicate ICP-MS inductively coupled plasma mass spectrometry FCR&D Fuel Cycle Research and Development K d distribution value MWCNT multiwall carbon nanotube SRNL Savannah River National Laboratory TSP titanosilicate having the pharmacosiderite structure Ion Exchange Performance 6

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