Structure and Thermal Transformations of Methylammonium Tungstate

Sukmana, Ndaru Candra; Sugiarto, _; Zhang, Zhenxin; Sadakane, Masahiro

doi:10.1002/zaac.202100219

Cited by 8 publications

(7 citation statements)

References 53 publications

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“…In addition to the appearance of H 2 O and CH 3 NH 2 , the degradation and oxidized species of methylammonium such as NH 3 , CO, N 2 , NO, CO 2 , and N 2 O were observed, indicating that a redox reaction between methylammonium and Mo has occurred under inert gas flow. Similar degradation and oxidation reactions of methylamine in methylammonium paradodecatungstate and vanadate under inert gas flow have been observed. , …”

Section: Resultssupporting

confidence: 70%

“…Similar degradation and oxidation reactions of methylamine in methylammonium paradodecatungstate and vanadate under inert gas flow have been observed. 22,23 In situ heating powder XRD experiments confirmed that structure transformation occurred during heating (Figure S9). The heating of (CH 3 NH 3 ) 2 [MoO 4 ] (Figure S9a Effect of Countercations on the Polyoxomolybdate Structure Produced by Solid-State Heating.…”

Section: Polyoxomolybdates Isolated From Aqueous Solutions Of Differe...mentioning

confidence: 89%

“…We have previously reported that the reaction of WO 3 and V 2 O 5 with the volatile base methylamine (CH 3 NH 2 ) and subsequent drying produced methylammonium paradodecatungstate, (CH 3 NH 3 ) 10 [H 2 W 12 O 42 ], 22 and methylammonium vanadate, CH 3 NH 3 [VO 3 ]. 23 In our previous communication, 24 we reported that dissolving MoO 3 in aqueous methylamine solution produced monomolybdate, [MoO 4 ] 2− , in solution, which could be isolated as methylammonium salt, (CH 3 Preparation of the Single Crystals of Polymeric ((CH 3 NH 3 ) 2 [(MoO 3 ) 3 (SO 4 )]) n .…”

Section: ■ Introductionmentioning

confidence: 99%

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Structure Transformation of Methylammonium Polyoxomolybdates via In-Solution Acidification and Solid-State Heating from Methylammonium Monomolybdate and Application as Negative Staining Reagents for Coronavirus Observation

Sukmana,

Sugiarto,

Shinogi

et al. 2024

Inorg. Chem.

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We prepared polyoxomolybdates with methylammonium countercations from methylammonium monomolybdate, (CH 3 NH 3 ) 2 [MoO 4 ], through two dehydrative condensation methods, acidifying in the aqueous solution and solid-state heating. Discrete (CH 3 NH 3 ) 10 [Mo 36 O 112 (OH) 2 (H 2 O) 14 ], polymeric ((CH 3 NH 3 ) 8 [Mo 36 O 112 (H 2 O) 14 ]) n, and polymeric ((CH 3 NH 3 ) 4 [γ-Mo 8 O 26 ]) n were selectively isolated via pH control of the aqueous (CH 3 NH 3 ) 2 [MoO 4 ] solution. The H 2 SO 4 -acidified solution of pH < 1 produced "sulfonated α-MoO 3 ", polymeric ((CH 3 NH 3 ) 2 [(MoO 3 ) 3 (SO 4 )]) n . The solid-state heating of (CH 3 NH 3 ) 2 [MoO 4 ] in air released methylamine and water to produce several methylammonium polyoxomolybdates in the sequence of discrete (CH 3 NH 3 ) 8 [Mo 7 O 24 −MoO 4 ], discrete (CH 3 NH 3 ) 6 [Mo 7 O 24 ], discrete (CH 3 NH 3 ) 8 [Mo 10 O 34 ], and polymeric ((CH 3 NH 3 ) 4 [γ-Mo 8 O 26 ]) n , before their transformation into molybdenum oxides such as hexagonal-MoO 3 and α-MoO 3 .Notably, some of their polyoxomolybdate structures were different from polyoxomolybdates produced from ammonium molybdates, such as (NH 4 ) 2 [MoO 4 ] or (NH 4 ) 6 [Mo 7 O 24 ], indicating that countercation affected the polyoxomolybdate structure. Moreover, among the tested polyoxomolybdates, (CH 3 NH 3 ) 6 [Mo 7 O 24 ] was the best negative staining reagent for the observation of the SARS-CoV-2 virus using transmission electron microscopy.

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Section: Resultssupporting

confidence: 70%

Section: Polyoxomolybdates Isolated From Aqueous Solutions Of Differe...mentioning

confidence: 89%

Section: ■ Introductionmentioning

confidence: 99%

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Structure Transformation of Methylammonium Polyoxomolybdates via In-Solution Acidification and Solid-State Heating from Methylammonium Monomolybdate and Application as Negative Staining Reagents for Coronavirus Observation

Sukmana,

Sugiarto,

Shinogi

et al. 2024

Inorg. Chem.

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“…Paratungstate-B is the dominant species in aqueous tungstate solution in a wide pH range and is isolable in the solid state. , The fact that octatungstate instead of paratungstate-B is formed in the presence of {Cp*Ir} 2+ indicates a structure-directing property of {Cp*Ir} 2+ . To test this hypothesis, we carried out a reaction between [(Cp*IrCl) 2 (μ-Cl) 2 ] and methylammonium paratungstate-B (CH 3 NH 3 ) 10 [H 2 W 12 O 42 ]which has a high solubility in wateras the tungsten source. The reaction produced an anionic Cp*Ir–octatungstate complex containing methylamine ligands [(Cp*Ir) 2 {Cp*Ir(NH 2 CH 3 )} 2 H 2 W 8 O 30 ] 2– ( 4a ) isolated as a methylammonium salt ( 4 ); 4a was also produced by adjusting the pH of a 1:2 [(Cp*IrCl) 2 (μ-Cl) 2 ]/Na 2 WO 4 mixture to 7.5–8.0 by the addition of aqueous methylamine solution from which it crystallized as Na[(Cp*Ir) 2 (μ-OH) 3 ][(Cp*Ir) 2 {Cp*Ir(NH 2 CH 3 )} 2 H 2 W 8 O 30 ] ( 4′ ).…”

Section: Resultsmentioning

confidence: 99%

Molar-Ratio-Dependent Coordination Assembly of Organoiridium(III)-Octatungstate Complexes in Aqueous Solution

2023

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We scrutinized the speciation of Cp*Ir-containing tungsten oxide clusters (Cp* is pentamethylcyclopentadienyl anion) in aqueous mixtures of [(Cp*IrCl)2(μ-Cl)2] and Na2WO4 in varying molar ratios. 1H nuclear magnetic resonance (NMR) spectroscopy revealed the formation of three distinct Cp*Ir–polyoxotungstate species in the reaction solution, and they were isolated as Na4[(Cp*Ir)2(μ-OH)3]2[(Cp*Ir)2H2W8O30] (1), [(Cp*Ir)2(μ-OH)3]2[(Cp*Ir)2{Cp*Ir(OH2)}2H2W8O30] (2), and [(Cp*Ir)2{Cp*Ir(OH2)}2{Cp*Ir(OH2)2}2H2W8O30](NO3)2 (3) from the mixtures in which iridium concentration is less than, equal to, and more than the tungsten concentration, respectively. These results show the octatungstate [H2W8O30]10– anion is the major polyoxotungstate species in the presence of {Cp*Ir}2+ cations, and it has high nucleophilicity enough to bind up to six {Cp*Ir}2+ cations on its surfaces producing a cationic Cp*Ir–octatungstate complex. The octatungstate anion was also generated from the reaction of [(Cp*IrCl)2(μ-Cl)2] and methylammonium paratungstate-B, (CH3NH3)10[H2W12O42], and was isolated as a methylamine-coordinated complex (CH3NH3)2[(Cp*Ir)2{Cp*Ir(NH2CH3)}2H2W8O30] (4), indicating {Cp*Ir}2+ cations function as a structure-directing agent that converts tungsten species into octatungstate anions in aqueous solution. In addition, the coordination environment of {Cp*Ir}2+ can be further modified by coordination with pyridine forming [{Cp*Ir(NC5H5)}2(μ-OH)2][(Cp*Ir)2{Cp*Ir(NC5H5)}2H2W8O30] (5).

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“…Structural analyses of polyoxometalates have mostly relied on X-ray or neutron diffraction to establish the solid-state structures of compounds that can be isolated and purified, complemented by spectroscopic tools such as multinuclear solution NMR, Raman, and X-ray spectroscopies. , An illustrative example is ammonium paratungstate (APT), [NH 4 ] 10 [H 2 W 12 O 42 ](H 2 O) x , which is the prototypical precursor to tungsten-derived materials, including W oxides, W alloys, and W-based catalysts . APT is poorly soluble in water and dissolves predominantly through conversion of the [H 2 W 12 O 42 ] 10– anion (paratungstate B) into the [W 7 O 24 ] 6– anion (paratungstate A), followed by aqueous phase speciation that depends on the pH, temperature, and nature of cations. , Solution 183 W NMR spectroscopy has long been recognized as a powerful tool for analyzing dissolved polyoxotungstates − due to the sensitivity of 183 W chemical shifts to local structures. For instance, for APT and related tungstates, it has been used to establish ion binding sites and the influence of pH and temperature on aqueous speciation .…”

mentioning

confidence: 99%

Solid-State ¹⁸³W NMR Spectroscopy as a High-Resolution Probe of Polyoxotungstate Structures and Dynamics

Berkson,

Bernhardt,

Copéret

2024

J. Phys. Chem. Lett.

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Polyoxometalates such as ammonium paratungstate (APT) constitute an important class of metal oxides with applications for catalysis, (opto)electronics, and functional materials. Structural analyses of solid polyoxometalates mostly rely on X-ray or neutron diffraction techniques, which are largely limited to compounds that can be isolated with long-range crystallographic order. While 183 W NMR has been shown to probe polyoxotungstate structures and dynamics in solution, its application to solids has been extremely limited. Here, state-of-the-art methods for the detection of solid-state 183 W NMR spectra are tested and compared for APT in different hydration states. The highly resolved solid-state spectra distinguish each crystallographically distinct site in the tungstate structure. Furthermore, the 183 W chemical shifts are shown to be highly sensitive to the local structure, dynamics, and symmetry of APT, establishing solid-state 183 W NMR spectroscopy as a potent probe for analysis of polyoxotungstates and other tungsten-derived materials to complement solution NMR and diffraction-based techniques.

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Structure and Thermal Transformations of Methylammonium Tungstate

Cited by 8 publications

References 53 publications

Structure Transformation of Methylammonium Polyoxomolybdates via In-Solution Acidification and Solid-State Heating from Methylammonium Monomolybdate and Application as Negative Staining Reagents for Coronavirus Observation

Structure Transformation of Methylammonium Polyoxomolybdates via In-Solution Acidification and Solid-State Heating from Methylammonium Monomolybdate and Application as Negative Staining Reagents for Coronavirus Observation

Molar-Ratio-Dependent Coordination Assembly of Organoiridium(III)-Octatungstate Complexes in Aqueous Solution

Solid-State ¹⁸³W NMR Spectroscopy as a High-Resolution Probe of Polyoxotungstate Structures and Dynamics

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Structure and Thermal Transformations of Methylammonium Tungstate

Cited by 8 publications

References 53 publications

Structure Transformation of Methylammonium Polyoxomolybdates via In-Solution Acidification and Solid-State Heating from Methylammonium Monomolybdate and Application as Negative Staining Reagents for Coronavirus Observation

Structure Transformation of Methylammonium Polyoxomolybdates via In-Solution Acidification and Solid-State Heating from Methylammonium Monomolybdate and Application as Negative Staining Reagents for Coronavirus Observation

Molar-Ratio-Dependent Coordination Assembly of Organoiridium(III)-Octatungstate Complexes in Aqueous Solution

Solid-State 183W NMR Spectroscopy as a High-Resolution Probe of Polyoxotungstate Structures and Dynamics

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Solid-State ¹⁸³W NMR Spectroscopy as a High-Resolution Probe of Polyoxotungstate Structures and Dynamics