High-temperature monoclinic α-SrHfF6, and isostructural α-SrZrF6: associating Hf2F12bipolyhedra and SrF8snub disphenoids

Laval, J.P.; Mayet, Richard

doi:10.1107/s2053229618001110

Cited by 6 publications

(21 citation statements)

References 59 publications

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“…The Sr cations are coordinated only by eight F2 atoms in a shape best described as a snub disphenoid (Johnson polyhedron J84). The Sr–F distances are 2.335(3) and 2.763(3) Å, and in good agreement to those reported for SrHfF 6 [2.376(3)–2.763(2) Å, P 2 1 / c , 293 K], where are also SrF 8 snub disphenoids are present . Therefore the Sr cations interconnect the [PbF 6 ] 2– anions only via their F2 atoms.…”

Section: Resultssupporting

confidence: 87%

Li₂PbF₆ and SrPbF₆ Revisited

Bandemehr

Deubner

Sachs

et al. 2018

Zeitschrift anorg allge chemie

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Herein we present the crystal structure of lithium hexafluoridoplumbate(IV) determined from powder X‐ray diffraction data. The cell parameters are a = 5.01067(3), c = 4.66340(5) Å, V = 101.3969(13) Å3 at T = 293 K. Li2PbF6 is isotypic to Li2ZrF6, space group P31m (no. 162). The measured Raman spectrum is compared with the quantum chemically calculated spectrum. Furthermore, we determined the decomposition temperature of Li2PbF6. We also present the corrected space group and crystal structure for SrPbF6 which was previously reported as P42/mmc (no. 131) and could now be corrected to space group P42/mcm [no. 132, a = 5.21719(3), c = 8.92771(11) Å, V = 243.004(4) Å3, T = 293 K].

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Section: Resultssupporting

confidence: 87%

Li₂PbF₆ and SrPbF₆ Revisited

Bandemehr

Deubner

Sachs

et al. 2018

Zeitschrift anorg allge chemie

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“…Upon incorporation of ZrF 4 , the nearest neighbor M−F peak broadens and moves to larger r. As six-coordinate Zr 4+ is smaller than six-coordinate Sc 3+ , the observed increase in the average M−F distance indicates that the solid solution samples must contain cations with a coordination number greater than six. It is notable that in β-BaZr 2 F 11 and α-SrHfF 6 , 28,29 which both contain pairs of edge-sharing Zr/HfF 7 polyehdra, the average M−F distance is 2.05 Å, consistent with the proposal that the observed increase in average M−F distance is associated with the creation of polyhedra with a coordination number greater than six. This is in agreement with the anion interstitial defect mechanism proposed based on the density measurements.…”

Section: Sample Purity and The Mechanism Of Excesssupporting

confidence: 82%

“…(b) A cartoon illustrating how corner-sharing polyhedra can be converted to edge-sharing polyhedra by incorporating excess fluoride into the structure. The 3.63 Å M–M distance and ∼2.05 Å M–F distance, marked for the pentagonal bipyramids, are approximately the M–M and average Zr/Hf–F distances found for pairs of edge-sharing MF 7 units in β -BaZr 2 F 11 and α -SrHfF 6 . , However, in reality, the edge-sharing pentagonal bipyramids are expected to be highly distorted due to the single shared edge.…”

Section: Resultsmentioning

confidence: 72%

“…A similar correlation peak was also observed for YbZrF 7 and the [Mg 1– x Zr x ]ZrF 6+2 x system and attributed to the metal pairs on the opposite sides of a shared polyhedral edge (see Figure b). It is notable that in β-BaZr 2 F 10 and α-SrHf 6 , which are well ordered and contain edge-sharing ZrF 7 and HfF 7 polyhedra, the Zr–Zr and Hf–Hf separations across a shared edge are 3.61 and 3.63 Å, respectively. The apparent shift in the correlation peak at ∼4 Å to longer distances upon the incorporation of zirconium can be attributed to an increase in the average nearest neighbor M–M distance for metals that share a single fluoride (corner-sharing polyhedra) rather than a pair of fluorides (edge-sharing polyhedral), see Figure b.…”

Section: Resultsmentioning

confidence: 99%

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Controlling the Phase Behavior of Low and Negative Thermal Expansion ReO₃-Type Fluorides using Interstitial Anions: Sc_1–xZr_xF_3+x

et al. 2020

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Density measurements suggest that the incorporation of ZrF4 into the cubic ReO3-type structure of Sc1– x Zr x F3+x is associated with the creation of anion interstitials. X-ray total scattering measurements are consistent with the conversion of corner-sharing octahedra to edge-sharing polyhedra as the solid solutions become richer in ZrF4. The cubic (Pm3̅m) to rhombohedral (R3̅c) cooperative octahedral tilting transition seen for ScF3 moves to a higher pressure as increasing amounts of zirconium are added, and it is eventually suppressed completely (x = 0.4 and 0.5) so that the cubic phase persists to high pressure until an amorphization occurs. All the samples studied (x = 0.0, 0.1, 0.2, 0.3, 0.4, and 0.5) display pressure-induced softening, and increasing the zirconium content leads to a higher zero-pressure bulk modulus. The incorporation of “excess fluoride” into ReO3-type fluorides is a powerful tool for suppressing the generally unwanted phase transitions seen when subjecting these materials to stress.

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“…This is consistent with a move away from corner sharing octahedra, where a single nearest neighbor F–F distance within each octahedron is expected, to more irregular geometry higher coordination number polyhedra, which are partially edge sharing. F–F pairs that lie on a shared edge are likely to be closer together, see for example β-BaZr 2 F 10 and α-SrHfF 6 , where distances of 2.38 and 2.35 Å, respectively, were reported for F–F pairs associated with the shared edges of two ZrF 7 or HfF 7 polyhedra. It is also notable that the Zr–Zr and Hf–Hf separations across this shared edge were 3.61 and 3.63 Å, respectively.…”

Section: Resultsmentioning

confidence: 99%

Controlling the Negative Thermal Expansion and Response to Pressure in ReO₃-type Fluorides by the Deliberate Introduction of Excess Fluoride: Mg_1–xZr_1+xF_6+2x, x = 0.15, 0.30, 0.40, and 0.50

et al. 2019

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Cubic ReO 3 -type fluorides often display negative or very low thermal expansion. However, they also typically undergo phase transitions upon cooling and/or modest compression, which are undesirable from the perspective of potential applications. Density measurements and total scattering data for Mg 1−x Zr 1+x F 6+2x , x = 0.15, 0.30, 0.40, and 0.50, indicate that the introduction of excess fluoride into cubic MgZrF 6 is accompanied by the population of interstitial fluoride sites and the conversion of corner to edge shared coordination polyhedra. Unlike MgZrF 6 , no phase transitions are seen upon cooling these materials to 10 K, and the first high pressure phase transition in these compositions occurs at pressures much higher than that previously reported for MgZrF 6 (0.37 GPa). The introduction of excess fluoride also provides for control of thermal expansion. For all of the compositions studied, negative thermal expansion is seen at the lowest temperature examined, and positive thermal expansion is observed at the highest temperature. The temperature at which zero thermal expansion occurs varies from ∼150 K for x = 0.50 to ∼500 K for x = 0.00. High pressure diffraction also indicates that increasing the amount of excess fluoride elastically stiffens the cubic ReO 3 related structure and reduces the extent of pressure induced softening.

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High-temperature monoclinic α-SrHfF₆, and isostructural α-SrZrF₆: associating Hf₂F₁₂bipolyhedra and SrF₈snub disphenoids

Cited by 6 publications

References 59 publications

Li₂PbF₆ and SrPbF₆ Revisited

Li₂PbF₆ and SrPbF₆ Revisited

Controlling the Phase Behavior of Low and Negative Thermal Expansion ReO₃-Type Fluorides using Interstitial Anions: Sc_1–xZr_xF_3+x

Controlling the Negative Thermal Expansion and Response to Pressure in ReO₃-type Fluorides by the Deliberate Introduction of Excess Fluoride: Mg_1–xZr_1+xF_6+2x, x = 0.15, 0.30, 0.40, and 0.50

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High-temperature monoclinic α-SrHfF6, and isostructural α-SrZrF6: associating Hf2F12bipolyhedra and SrF8snub disphenoids

Cited by 6 publications

References 59 publications

Li2PbF6 and SrPbF6 Revisited

Li2PbF6 and SrPbF6 Revisited

Controlling the Phase Behavior of Low and Negative Thermal Expansion ReO3-Type Fluorides using Interstitial Anions: Sc1–xZrxF3+x

Controlling the Negative Thermal Expansion and Response to Pressure in ReO3-type Fluorides by the Deliberate Introduction of Excess Fluoride: Mg1–xZr1+xF6+2x, x = 0.15, 0.30, 0.40, and 0.50

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High-temperature monoclinic α-SrHfF₆, and isostructural α-SrZrF₆: associating Hf₂F₁₂bipolyhedra and SrF₈snub disphenoids

Li₂PbF₆ and SrPbF₆ Revisited

Li₂PbF₆ and SrPbF₆ Revisited

Controlling the Phase Behavior of Low and Negative Thermal Expansion ReO₃-Type Fluorides using Interstitial Anions: Sc_1–xZr_xF_3+x

Controlling the Negative Thermal Expansion and Response to Pressure in ReO₃-type Fluorides by the Deliberate Introduction of Excess Fluoride: Mg_1–xZr_1+xF_6+2x, x = 0.15, 0.30, 0.40, and 0.50