On the Crystal Chemistry of Inorganic Nitrides: Crystal-Chemical Parameters and Opportunities in the Exploration of Their Compositional Space

Gagné, Olivier Charles

doi:10.26434/chemrxiv.11626974.v2

Cited by 2 publications

(2 citation statements)

References 82 publications

(144 reference statements)

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“…Ternary metal nitrides remain under-explored as new functional inorganic materials, 1 even though a large number of new nitride compositions and structure types have been recently predicted. [2][3][4][5] The underutilized potential of nitride materials stems from their difficult synthesis, with few successful reactions that do not require extreme temperature or pressure conditions. This is because molecules with nitrogen triple bonds, including dinitrogen, have some of the strongest chemical bonds, 6 and because inorganic nitrides are often highly refractory materials used in ultra-hard coatings (TiN, Si 3 N 4 ) 7 and high temperature lubricants (BN).…”

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confidence: 99%

Two-step solid-state synthesis of ternary nitride materials

Todd¹,

Fallon²,

Neilson³

et al. 2021

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Ternary nitrides with strong metal-nitrogen bonds are an emerging class of inorganic materials for use in a variety of optical, electronic, and refractory applications. However at the elevated synthesis temperatures, entropy favors formation of strong dinitrogen triple bonds, which is often counteracted at high reaction pressures, making synthesis process difficult.Here we report on a simple two-step ion-exchange synthesis of MgZrN 2 and Mg 2 NbN 3 with rocksalt-derived structure as well as the MgMoN 2 with layered hexagonal structure, whereas the corresponding one-step reactions lead to decomposition into binaries. Differential Scanning Calorimetry reveals that the first low-temperature reaction step is facilitated at phase transition temperatures of chloride precursors, which promotes the local ternary Mg−TM−N bond formation. Overall, these results demonstrate a low-temperature ambient-pressure approach to synthesize new ternary nitride materials.

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confidence: 99%

Two-step solid-state synthesis of ternary nitride materials

Todd¹,

Fallon²,

Neilson³

et al. 2021

Preprint

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“…While this series has focused on bonds to oxygen, it is desirable that similar studies be done in the future for other anions; Gagné recently published a similar study for cations bonded to N 3-in inorganic compounds. 28 This article is the fifth and last of a series in which we describe bond-length data for ions bonded to oxygen in inorganic crystals. In this series, we have examined the distribution of bond lengths for 135 ions bonded to oxygen in 460 configurations (on the basis of coordination number), using 177,446 bond lengths extracted from 9210 crystal structures refined since 1975; these data cover most ions of the periodic table and the coordination environment in which they occur in inorganic compounds.…”

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confidence: 99%

Bond-Length Distributions for Ions Bonded to Oxygen: Results for the Transition Metals and Quantification of the Factors Underlying Bond-Length Variation in Inorganic Solids

Gagné¹,

Hawthorne²

2020

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Bond-length distributions are examined for 63 transition-metal ions bonded to O2- in 147 configurations, for 7522 coordination polyhedra and 41,488 bond distances, providing baseline statistical knowledge of bond lengths for transi-tion metals bonded to O2-. A priori bond valences are calculated for 140 crystal structures containing 266 coordination poly-hedra for 85 transition-metal ion configurations with anomalous bond-length distributions. Two new indices, Δ𝑡𝑜𝑝𝑜𝑙 and Δ𝑐𝑟𝑦𝑠𝑡, are proposed to quantify bond-length variation arising from bond-topological and crystallographic effects in extended solids. Bond-topological mechanisms of bond-length variation are [1] non-local bond-topological asymmetry, and [2] multi-ple-bond formation; crystallographic mechanisms are [3] electronic effects (with inherent focus on coupled electronic-vibra-tional degeneracy in this work), and [4] crystal-structure effects. The Δ𝑡𝑜𝑝𝑜𝑙 and Δ𝑐𝑟𝑦𝑠𝑡 indices allow one to determine the primary cause(s) of bond-length variation for individual coordination polyhedra and ion configurations, quantify the dis-torting power of cations via electronic effects (by subtracting the bond-topological contribution to bond-length variation), set expectation limits regarding the extent to which functional properties linked to bond-length variations may be optimized in a given crystal structure (and inform how optimization may be achieved), and more. We find the observation of multiple bonds to be primarily driven by the bond-topological requirements of crystal structures in solids. However, we sometimes observe multiple bonds to form as a result of electronic effects (e.g. the pseudo Jahn-Teller effect); resolution of the origins of multiple-bond formation follows calculation of the Δ𝑡𝑜𝑝𝑜𝑙 and Δ𝑐𝑟𝑦𝑠𝑡 indices on a structure-by-structure basis. Non-local bond-topological asymmetry is the most common cause of bond-length variation in transition-metal oxides and oxysalts, followed closely by the pseudo Jahn-Teller effect (PJTE). Non-local bond-topological asymmetry is further suggested to be the most widespread cause of bond-length variation in the solid state, with no a priori limitations with regard to ion identity. Overall, bond-length variations resulting from the PJTE are slightly larger than those resulting from non-local bond-topological asym-metry, comparable to those resulting from the strong JTE, and less than those induced by π-bond formation. From a compar-ison of a priori and observed bond valences for ~150 coordination polyhedra in which the strong JTE or the PJTE is the main reason underlying bond-length variation, the Jahn-Teller effect is found not to have a symbiotic relation with the bond-topo-logical requirements of crystal structures. The magnitude of bond-length variations caused by the PJTE decreases in the fol-lowing order for octahedrally coordinated d0 transition metals oxyanions: Os8+ > Mo6+ > W6+ >> V5+ > Nb5+ > Ti4+ > Ta5+ > Hf4+ > Zr4+ > Re7+ >> Y3+ > Sc3+. Such ranking varies by coordination number; for [4], it is Re7+ > Ti4+ > V5+ > W6+ > Mo6+ > Cr6+ > Os8+ >> Mn7+; for [5], it is Os8+ > Re7+ > Mo6+ > Ti4+ > W6+ > V5+ > Nb5+. We conclude that non-octahedral coordinations of d0 ion configurations are likely to occur with bond-length variations that are similar in magnitude to their octahedral counterparts. However, smaller bond-length variations are expected from the PJTE for non-d0 transition-metal oxyanions.<br>

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On the Crystal Chemistry of Inorganic Nitrides: Crystal-Chemical Parameters and Opportunities in the Exploration of Their Compositional Space

Cited by 2 publications

References 82 publications

Two-step solid-state synthesis of ternary nitride materials

Two-step solid-state synthesis of ternary nitride materials

Bond-Length Distributions for Ions Bonded to Oxygen: Results for the Transition Metals and Quantification of the Factors Underlying Bond-Length Variation in Inorganic Solids

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