Neutron powder diffraction – new opportunities in hydrogen location in molecular and materials structure

Wilson, Chick C.; Henry, Paul; Schmidtmann, Marc; Ting, Valeska P.; Williams, Edward R.; Weller, Mark T.

doi:10.1080/0889311x.2014.886202

Cited by 12 publications

(3 citation statements)

References 91 publications

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“…Given that complete removal of excess DMF and Me-bdc was not possible without structural degradation, there is considerable incoherent scattering due to hydrogen. However, Weller et al, 70,71 as well as our previous MOF work, 72 have shown that neutron powder diffraction is quite possible with various amounts of hydrogen in crystalline materials, with hydrogen positions readily accessible due to their negative contrast. It is understandable that due to the amount of hydrogen, as well as the large unit cell, the patterns do not contain much information beyond Q = 2 Å −1 , despite containing sharp crystalline peaks.…”

Section: ■ Experimental Sectionmentioning

confidence: 86%

Understanding Gas Storage in Cuboctahedral Porous Coordination Cages

Lorzing¹,

Gosselin²,

Trump

et al. 2019

J. Am. Chem. Soc.

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Porous molecular solids are promising materials for gas storage and gas separation applications. However, given the relative dearth of structural information concerning these materials, additional studies are vital for further understanding their properties and developing design parameters for their optimization. Here, we examine a series of isostructural cuboctahedral, paddlewheel-based coordination cages, M24(tBu-bdc)24 (M = Cr, Mo, Ru; tBu-bdc2− = 5-tert-butylisophthalate), for high-pressure methane storage. As the decrease in crystallinity upon activation of these porous molecular materials precludes diffraction studies, we turn to a related class of pillared coordination cage-based metal-organic frameworks, M24(Me-bdc)24(dabco)6 (M = Fe, Co; Me-bdc2− = 5-methylisophthalate; dabco = 1,4-diazabicyclo[2.2.2]octane) for neutron diffraction studies. The five porous materials display BET surface areas from 1,057 – 1,937 m2/g and total methane uptake capacities of up to 143 cm3(STP)/cm3. Both the porous cages and cage-based frameworks display methane adsorption enthalpies of −15 to −22 kJ/mol. Also supported by molecular modeling, neutron diffraction studies indicate that the triangular windows of the cage are favorable methane adsorption sites with CD4-arene interactions between 3.7 and 4.1 Å. At both low and high loadings, two additional methane adsorption sites on the exterior surface of the cage are apparent for a total of 56 adsorption sites per cage. These results show that M24L24 cages are competent gas storage materials and further adsorption sites may be optimized by judicious ligand functionalization to control extra-cage pore space.

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Section: ■ Experimental Sectionmentioning

confidence: 86%

Understanding Gas Storage in Cuboctahedral Porous Coordination Cages

Lorzing¹,

Gosselin²,

Trump

et al. 2019

J. Am. Chem. Soc.

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“…These yield data with low diffraction peak intensities on very large backgrounds requiring very long data collection times and, generally, yielding structural models with lower precision. Neutron source and instrument developments have resulted in new possibilities to study hydrogenous materials without the requirement, cost and associated problems to deuterate, [44][45][46] while also offering relatively short counting times 47 and prospects to take advantage of the scattering length contrast of H cf. D (−3.739 fm and 6.671 fm respectively).…”

Section: Discussionmentioning

confidence: 99%

The influence of cation ordering, oxygen vacancy distribution and proton siting on observed properties in ceramic electrolytes: the case of scandium substituted barium titanate

et al. 2017

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The origin of the 2-order of magnitude difference in the proton conductivity of the hydrated forms of hexagonal and cubic oxygen deficient BaScTiO (x = 0.2 and x = 0.7) was probed using a combination of neutron diffraction and density functional theory techniques to support published X-ray diffraction, conductivity, thermogravimetric and differential scanning calorimetry studies. Cation ordering is found in the 6H structure type (space group P6/mmc) adopted by BaScTiO with scandium preferentially substituting in the vertex sharing octahedra (2a crystallographic site) and avoiding the face-sharing octahedra (4f site). This is coupled with oxygen vacancy ordering in the central plane of the face-sharing octahedra (O1 site). In BaScTiO a simple cubic perovskite (space group Pm3[combining macron]m) best represents the average structure from Rietveld analysis with no evidence of either cation ordering or oxygen vacancy ordering. Significant diffuse scattering is observed, indicative of local order. Hydration in both cases leads to complete filling of the available oxygen vacancies and permits definition of the proton sites. We suggest that the more localised nature of the proton sites in the 6H structure is responsible for the significantly lower proton conduction observed in the literature. Within the 6H structure type final model, proton diffusion requires a 3-step process via higher energy proton sites that are unoccupied at room temperature and is also likely to be anisotropic whereas the highly disordered cubic perovskite proton position allows 3-dimensional diffusion by well-described modes. Finally, we propose how this knowledge can be used to further materials design for ceramic electrolytes for proton conducting fuel cells.

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“…[41] Neutron powder diffraction, still a relatively new method, has emerged as a valuable tool for investigations of phase transitions at high pressures. [42][43][44] …”

Section: Neutron Diffraction: Locating the Hydrogen Atomsmentioning

confidence: 98%

Crystal structures of amino acids: from bond lengths in glycine to metal complexes and high-pressure polymorphs

Görbitz

2015

Crystallography Reviews

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After the discovery of X-ray diffraction by crystals, amino acids were among the first organic compounds to have their solid-state structures investigated. The Cambridge Structural Database now contains more than 3500 entries for α-amino acids alone. After a short introduction dealing with the early history of X-ray structure determination, this review provides a classification of amino acid structures, describes essential structural elements, especially hydrogen bonding preferences and coordination to metal ions, and considers recent investigations on phase transitions as the result of extreme temperatures or pressure.

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Neutron powder diffraction – new opportunities in hydrogen location in molecular and materials structure

Cited by 12 publications

References 91 publications

Understanding Gas Storage in Cuboctahedral Porous Coordination Cages

Understanding Gas Storage in Cuboctahedral Porous Coordination Cages

The influence of cation ordering, oxygen vacancy distribution and proton siting on observed properties in ceramic electrolytes: the case of scandium substituted barium titanate

Crystal structures of amino acids: from bond lengths in glycine to metal complexes and high-pressure polymorphs

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