Elucidating Negative Thermal Expansion in MOF-5

Lock, Nina; Wu, Yirong; Christensen, Mogens; Cameron, Lisa J.; Peterson, Vanessa K.; Bridgeman, Adam J.; Kepert, Cameron J.; Iversen, Bo B.

doi:10.1021/jp103212z

Cited by 223 publications

(259 citation statements)

References 36 publications

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“…19 H-MOF-5 powders were used for INS, EXAFS and powder X-ray diffraction, whereas D-MOF-5 was used for powder and single-crystal X-ray and neutron diffraction. In the following the term "guest free" MOF-5 is used when the crystal pores are considered completely empty, i.e.…”

Section: Resultsmentioning

confidence: 99%

Scrutinizing negative thermal expansion in MOF-5 by scattering techniques and ab initio calculations

Lock

Christensen

et al. 2013

Dalton Trans.

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Complementary experimental techniques and ab initio calculations were used to determine the origin and nature of negative thermal expansion (NTE) in the archetype metal-organic framework MOF-5 (Zn(4)O(1,4-benzenedicarboxylate)(3)). The organic linker was probed by inelastic neutron scattering under vacuum and at a gas pressure of 175 bar to distinguish between the pressure and temperature responses of the framework motions, and the local structure of the metal centers was studied by X-ray absorption spectroscopy. Multi-temperature powder- and single-crystal X-ray and neutron diffraction was used to characterize the polymeric nature of the sample and to quantify NTE over the large temperature range 4-400 K. Ab initio calculations complement the experimental data with detailed information on vibrational motions in the framework and their correlations. A uniform and comprehensive picture of NTE in MOF-5 has been drawn, and we provide direct evidence that the main contributor to NTE is translational transverse motion of the aromatic ring, which can be dampened by applying a gas pressure to the sample. The linker motion is highly correlated rather than local in nature. The relative energies of different framework vibrations populated in MOF-5 are suggested by analysis of neutron diffraction data. We note that the lowest-energy motion is a librational motion of the aromatic ring which does not contribute to NTE. The libration is followed by transverse motion of the linker and the carboxylate group. These motions result in unit-cell contraction with increasing temperature.

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Section: Resultsmentioning

confidence: 99%

Scrutinizing negative thermal expansion in MOF-5 by scattering techniques and ab initio calculations

Lock

Christensen

et al. 2013

Dalton Trans.

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“…(1)). MOFs' heat capacity, together with a consistent set of other thermophysical properties like thermal conductivity, enthalpy and entropy [6,7] is fundamental also to develop a detailed understanding of several phenomena including multiferroic phase transitions [8e10], temperature-induced lattice dynamics, negative thermal expansion [11] and thermal stability [12]. While the literature is replete with MOFs' synthesis, gas adsorption isotherms and isosteric heat data, measurements on their specific heats are far less common.…”

Section: Introductionmentioning

confidence: 99%

Specific heat capacities of MOF-5, Cu-BTC, Fe-BTC, MOF-177 and MIL-53 (Al) over wide temperature ranges: Measurements and application of empirical group contribution method

Kloutse

Zacharia

Cossement

et al. 2015

Microporous and Mesoporous Materials

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“…MOF-5 is unusual in that it shows quite a large variation in volume under ambient-pressure conditions, ranging from 16 913.2 (3) 3 (for a completely desolvated sample at 213 K) to 17 369.9 (1) 3 (for an N 2 -containing material at 30 K). [13,14] In fact, MOF-5 has previously demonstrated negative thermal expansion behavior. [15] It is therefore unsurprising that the calculated values at ambient pressure determined here are larger than the experimental data recorded at 30 K. Nevertheless, the calculated geometrical data are within 2.6 % of the experimental values and correlate closely with the results of a previous ab initio study by Civalleri et al, [16] which helps to validate the computational approach.…”

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The Effect of High Pressure on MOF‐5: Guest‐Induced Modification of Pore Size and Content at High Pressure

et al. 2011

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Grace under pressure: In the first high‐pressure crystallographic study on the metal–organic framework MOF‐5, increasing pressure initially results in the pressure‐transmitting fluid being squeezed into the pores. Further pressure increase causes a large reduction in pore content as solvent is evacuated from the pores, until a complete loss of crystallinity is observed at pressures above 3.2 GPa.

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Elucidating Negative Thermal Expansion in MOF-5

Cited by 223 publications

References 36 publications

Scrutinizing negative thermal expansion in MOF-5 by scattering techniques and ab initio calculations

Scrutinizing negative thermal expansion in MOF-5 by scattering techniques and ab initio calculations

Specific heat capacities of MOF-5, Cu-BTC, Fe-BTC, MOF-177 and MIL-53 (Al) over wide temperature ranges: Measurements and application of empirical group contribution method

The Effect of High Pressure on MOF‐5: Guest‐Induced Modification of Pore Size and Content at High Pressure

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