Positional disorder in ammonia borane at ambient conditions

Welchman, Evan; Giannozzi, Paolo; Thonhauser, Timo

doi:10.1103/physrevb.89.180101

Cited by 5 publications

(6 citation statements)

References 31 publications

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“…tentials,G aussian basis-sets, all-electron augmented plane waves). [75] Recently,t he calculated values fort he equationo fs tates were compared using 40 different DFTm ethodt ypes showing that deviations between the accurate codes are smaller than those of experiments.…”

Section: Theoretical Quantum Crystallographymentioning

confidence: 99%

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Quantum Crystallography: Current Developments and Future Perspectives

Genoni

Bučinský

Claiser

et al. 2018

Chemistry A European J

123

114

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Crystallography and quantum mechanics have always been tightly connected because reliable quantum mechanical models are needed to determine crystal structures. Due to this natural synergy, nowadays accurate distributions of electrons in space can be obtained from diffraction and scattering experiments. In the original definition of quantum crystallography (QCr) given by Massa, Karle and Huang, direct extraction of wavefunctions or density matrices from measured intensities of reflections or, conversely, ad hoc quantum mechanical calculations to enhance the accuracy of the crystallographic refinement are implicated. Nevertheless, many other active and emerging research areas involving quantum mechanics and scattering experiments are not covered by the original definition although they enable to observe and explain quantum phenomena as accurately and successfully as the original strategies. Therefore, we give an overview over current research that is related to a broader notion of QCr, and discuss options how QCr can evolve to become a complete and independent domain of natural sciences. The goal of this paper is to initiate discussions around QCr, but not to find a final definition of the field.

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Section: Theoretical Quantum Crystallographymentioning

confidence: 99%

“…[74] As af urthere xample, the usage of modernn on-local functionals coupled with molecular dynamics has allowed to interpret experimental resultsi nm olecular crystalsa tf inite temperature. [75]…”

Section: Theoretical Quantum Crystallographymentioning

confidence: 99%

Quantum Crystallography: Current Developments and Future Perspectives

Genoni

Bučinský

Claiser

et al. 2018

Chemistry A European J

123

114

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“…The additional height of these barriers is due to disruption of the material's dihydrogen bond network, which is much more rigid in the low-temperature phase we are using for our simulations. In a previous study, 39 we found that signicant barriers to disrupting this network (by rotating molecules, for instance) do not exist in the roomtemperature phase of pure AB, where the desorption reaction occurs experimentally. However, the most striking result in Table 7 is that the kinetic barriers for H 2 desorption in the Cu-substituted material are signicantly lower than those of pure AB.…”

Section: H 2 Release Barriers In the Bulkmentioning

confidence: 78%

Lowering the hydrogen desorption temperature of NH₃BH₃ through B-group substitutions

Welchman

Thonhauser

2015

J. Mater. Chem. A

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We present ab initio results for substitutions in the promising hydrogen-storage material NH 3 BH 3 to lower its hydrogen desorption temperature. Substitutions have already been investigated with significant success recently, but in all cases a less electronegative element is substituted for the protic hydrogen in the NH 3 group of NH 3 BH 3 . We propose a different route, substituting the hydridic hydrogen in the BH 3 group with a more electronegative element. To keep the gravimetric density high, we focus on the second period elements C, N, O, and F, all with higher electronegativity compared to H. In addition, we investigate Cu and S as possible substitutions. Our main results include Bader charge analyses, hydrogen binding energies, and kinetic barriers for the hydrogen release reaction in the gas phase as well as in the solid. While the different substituents show varying effects on the kinetic barrier and thus desorption temperature-some overshoot our goal while others have little effect-we identify Cu as a very promising substituent, which lowers the reaction barrier by approximately 37% compared to NH 3 BH 3 and thus significantly influences the hydrogen desorption temperature.

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“…The RDFs discussed above are averaged over orientational degrees of freedom and, therefore, cannot directly quantify orientational order in the acetylene:ammonia (1:1) co-crystal. To quantify the orientational structure of ammonia molecules within the co-crystal, we compute the probability distribution of ammonia H atom positions projected on the xz plane of the crystal . At 30 K, the ammonia molecules are orientationally ordered, as reflected by the distinct, disconnected regions of high probability, Figure a.…”

Section: Resultsmentioning

confidence: 99%

Molecular Structure, Dynamics, and Vibrational Spectroscopy of the Acetylene:Ammonia (1:1) Plastic Co-Crystal at Titan Conditions

Thakur

Remsing

2023

ACS Earth Space Chem.

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The Saturnian moon Titan has a thick, organic-rich atmosphere, and condensed phases of small organic molecules are anticipated to be stable on its surface. Of particular importance are crystalline phases of organics, known as cryominerals, which can play important roles in surface chemistry and geological processes on Titan. Many of these cryominerals could exhibit rich phase behavior, especially multicomponent cryominerals whose component molecules have multiple solid phases. One such cryomineral is the acetylene:ammonia (1:1) co-crystal, and here we use density functional theory-based ab initio molecular dynamics simulations to quantify its structure and dynamics at Titan conditions. We show that the acetylene:ammonia (1:1) co-crystal is a plastic co-crystal (or rotator phase) at Titan conditions because the ammonia molecules are orientationally disordered. Moreover, the ammonia molecules within this co-crystal rotate on picosecond time scales, and this rotation is accompanied by the breakage and reformation of hydrogen bonds between the ammonia hydrogens and the π-system of acetylene. The robustness of our predictions is supported by comparing the predictions of two density functional approximations at different levels of theory, as well as through the prediction of infrared and Raman spectra that agree well with experimental measurements. We anticipate that these results will aid in understanding geochemistry on the surface of Titan.

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Positional disorder in ammonia borane at ambient conditions

Cited by 5 publications

References 31 publications

Quantum Crystallography: Current Developments and Future Perspectives

Quantum Crystallography: Current Developments and Future Perspectives

Lowering the hydrogen desorption temperature of NH₃BH₃ through B-group substitutions

Molecular Structure, Dynamics, and Vibrational Spectroscopy of the Acetylene:Ammonia (1:1) Plastic Co-Crystal at Titan Conditions

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Positional disorder in ammonia borane at ambient conditions

Cited by 5 publications

References 31 publications

Quantum Crystallography: Current Developments and Future Perspectives

Quantum Crystallography: Current Developments and Future Perspectives

Lowering the hydrogen desorption temperature of NH3BH3 through B-group substitutions

Molecular Structure, Dynamics, and Vibrational Spectroscopy of the Acetylene:Ammonia (1:1) Plastic Co-Crystal at Titan Conditions

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Lowering the hydrogen desorption temperature of NH₃BH₃ through B-group substitutions