High Resolution 15N NMR of the 225 K Phase Transition of Ammonia Borane (NH3BH3):  Mixed Order-Disorder and Displacive Behavior

Günaydın-Şen, Özge; Achey, R. M.; Dalal, N. S.; Stowe, Ashley C.; Autrey, Tom

doi:10.1021/jp0649347

Cited by 51 publications

(59 citation statements)

References 44 publications

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“…Such a transition is typical of second-order phase transformations. Our observations of modulus pre-softening are complementary and coherent with previous NMR results in NH 3 BH 3 [8], and make the above hypothesis of B-N axis dynamics more solid.…”

Section: Discussionsupporting

confidence: 90%

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The tetragonal-to-orthorhombic phase transformation in ammonia borane and in its deuterium substituted compounds

Palumbo

Paolone

Rspoli

et al. 2011

Journal of Alloys and Compounds

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Section: Discussionsupporting

confidence: 90%

“…It has been suggested [8] that the transition is triggered by the slowing down of the NH 3 motion, but at present the mechanism driving the phase transformation is not well understood.…”

Section: Introductionmentioning

confidence: 99%

The tetragonal-to-orthorhombic phase transformation in ammonia borane and in its deuterium substituted compounds

Palumbo

Paolone

Rspoli

et al. 2011

Journal of Alloys and Compounds

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“…Interest in this bond is reflected in a series of important papers addressing its inelastic neutron scattering [3] and its 225 K phase transition, studied using high-resolution solidstate 15 N NMR spectroscopy. [4] In addition, the structures of methylamine borane molecules (Me n H 3Àn N:BH 3 , n = 1-3) have been investigated using X-ray diffraction, gas-phase electron diffraction, and quantum chemical calculations. [5] Plumley and Evanseck have discussed the covalent and ionic nature of the dative bond in ammonia borane based on high-level QCISD(T) calculations, [6] and Anane et al have carried out a comparison of the B À N with the B À P bond [7] by comparing H 3 N:BX 3 with H 3 P:BX 3 (X = H, F, Cl) at the G2/MP2 level.…”

Section: Introductionmentioning

confidence: 99%

New Insights into Factors Influencing BN Bonding in X:BH_3−nF_nand X:BH_3−nCl_nfor X=N₂, HCN, LiCN, H₂CNH, NF₃, NH₃andn=0–3: The Importance of Deformation

Alkorta

Elguero

Bene

et al. 2010

Chemistry A European J

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Understanding the bonding in complexes X:BH(3-n)F(n) and X:BH(3-n)Cl(n), for X=N(2), HCN, LiCN, H(2)CNH, NF(3), NH(3) with n=0-3, is a challenging task. The trends in calculated binding energies cannot be explained in terms of any of the usual indexes, including π donation from the halogen lone pairs to the p(π) empty orbital on B, deformation energies, charge capacities, or LUMO energies, which are normally invoked to explain the higher Lewis acidity of BCl(3) relative to BF(3). The results of the high-level G3B3 ab initio calculations reported in this study suggest that the interaction energies of these complexes are determined by a combination of at least three factors. These include the decrease in the electron-accepting ability of B as a result of π donation by the halogen atom, the increase in the electron-acceptor capacity of B due to deformation of the acid, and the large increase in the deformation energy of the acid with increasing halogen substitution. The dominant effects are those derived from the electronic effects of acid deformation. Deformation not only has direct energetic consequences, which are reflected in the large differences between dissociation (D(0)) and interaction (E(int)) energies, but also leads to an enhancement of the intrinsic acidities of BH(3-n)F(n) and BH(3-n)Cl(n) moieties by lowering the LUMO energies to very different extents, consistent with the frontier orbital model of chemical reactivity. Although this lowering depends on both the number and the nature of the halogen substituents, binding energies do not systematically increase or decrease as the number of halogen atoms increases.

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“…22 At ambient conditions ammonia borane crystallizes in a tetragonal space group I4mm with a unit cell containing two molecules. 23,24 NMR measurements 25,26 revealed that the NH 3 and BH 3 groups undergo motion about the B-N bond. This motion freezes out at low temperature and at about T t = 225 K a first order rotational order-disorder phase transition with a change in structure from body-centered tetragonal ͑bct͒ to orthorhombic ͑space group Pmn2 1 ͒ occurs.…”

Section: Introductionmentioning

confidence: 99%

Raman spectroscopy study of ammonia borane at high pressure

Lin

Mao

Drozd

et al. 2008

The Journal of Chemical Physics

100

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Ammonia borane, NH(3)BH(3), has attracted significant interest as a promising candidate material for hydrogen storage. The effect of pressure on the bonding in NH(3)BH(3) was investigated using Raman spectroscopy to over 20 GPa in a diamond anvil cell, and two new transitions were observed at approximately 5 and 12 GPa. Vibrational frequencies for the modes of the NH(3) proton donor group exhibited negative pressure dependence, which is consistent with the behavior of conventional hydrogen bonds, while the vibrational frequencies of the BH(3) proton acceptor group showed positive pressure dependence. The observed behavior of these stretching modes supports the presence of dihydrogen bonding at high pressure. In addition, the BH(3) and NH(3) bending modes showed an increase in spectral complexity with increasing pressure together with a discontinuity in d nu/d P which suggests rotational disorder in this molecule. These results may provide guidance for understanding and developing improved hydrogen storage materials.

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High Resolution ¹⁵N NMR of the 225 K Phase Transition of Ammonia Borane (NH₃BH₃): Mixed Order-Disorder and Displacive Behavior

Cited by 51 publications

References 44 publications

The tetragonal-to-orthorhombic phase transformation in ammonia borane and in its deuterium substituted compounds

The tetragonal-to-orthorhombic phase transformation in ammonia borane and in its deuterium substituted compounds

New Insights into Factors Influencing BN Bonding in X:BH_3−nF_nand X:BH_3−nCl_nfor X=N₂, HCN, LiCN, H₂CNH, NF₃, NH₃andn=0–3: The Importance of Deformation

Raman spectroscopy study of ammonia borane at high pressure

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High Resolution 15N NMR of the 225 K Phase Transition of Ammonia Borane (NH3BH3): Mixed Order-Disorder and Displacive Behavior

Cited by 51 publications

References 44 publications

The tetragonal-to-orthorhombic phase transformation in ammonia borane and in its deuterium substituted compounds

The tetragonal-to-orthorhombic phase transformation in ammonia borane and in its deuterium substituted compounds

New Insights into Factors Influencing BN Bonding in X:BH3−nFnand X:BH3−nClnfor X=N2, HCN, LiCN, H2CNH, NF3, NH3andn=0–3: The Importance of Deformation

Raman spectroscopy study of ammonia borane at high pressure

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Product

Resources

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High Resolution ¹⁵N NMR of the 225 K Phase Transition of Ammonia Borane (NH₃BH₃): Mixed Order-Disorder and Displacive Behavior

New Insights into Factors Influencing BN Bonding in X:BH_3−nF_nand X:BH_3−nCl_nfor X=N₂, HCN, LiCN, H₂CNH, NF₃, NH₃andn=0–3: The Importance of Deformation