Low temperature phase transition induced biaxial negative thermal expansion of 2,4-dinitroanisole

Takahashi, Hiroki; Tamura, Rui

doi:10.1039/c5ce00029g

Cited by 24 publications

(23 citation statements)

References 43 publications

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“…Structure-property relationships in crystalline materials are of fundamental importance for a huge range of research and practical applications, and the control and design of such properties is at the heart of crystal engineering. For molecular materials, thermal expansion has received some attention in the literature, for example where structures show unusually large or exceptionally anisotropic expansion (Das et al, 2010;Takahashi & Tamura, 2015;Alimi et al, 2018;van der Lee et al, 2018;Liu et al, 2019). There have also been some efforts in the crystal engineering literature to link thermal expansion to intermolecular interactions and specific structural features Bhattacharya & Saha, 2014;Saraswatula et al, 2015;Hutchins et al, 2016;Rather & Saha, 2018;Hutchins et al, 2018a;Negi et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

A survey of thermal expansion coefficients for organic molecular crystals in the Cambridge Structural Database

Bond¹

2021

Acta Crystallogr B Struct Sci Cryst Eng Mater

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Typical ranges of thermal expansion coefficients are established for organic molecular crystals in the Cambridge Structural Database. The CSD Python API is used to extract 6201 crystal structures determined close to room temperature and at least one lower temperature down to 90 K. The data set is dominated by structure families with only two temperature points and is subject to various sources of error, including incorrect temperature reporting and missing flags for variable-pressure studies. For structure families comprising four or more temperature points in the range 90–300 K, a linear relationship between unit-cell volume and temperature is shown to be a reasonable approximation. For a selected subset of 210 structures showing an optimal linear fit, the volumetric expansion coefficient at 298 K has mean 173 p.p.m. K−1 and standard deviation 47 p.p.m. K−1. The full set of 6201 structures shows a similar distribution, which is fitted by a normal distribution with mean 161 p.p.m. K−1 and standard deviation 51 p.p.m. K−1, with excess population in the tails mainly comprising unreliable entries. The distribution of principal expansion coefficients, extracted under the assumption of a linear relationship between length and temperature, shows a positive skew and can be approximated by two half normal distributions centred on 33 p.p.m. K−1 with standard deviations 40 p.p.m. K−1 (lower side) and 56 p.p.m. K−1 (upper side). The distribution for the full structure set is comparable to that of the test subset, and the overall frequency of biaxial and uniaxial negative thermal expansion is estimated to be < 5% and ∼30%, respectively. A measure of the expansion anisotropy shows a positively skewed distribution, similar to the principal expansion coefficients themselves, and ranges based on suggested half normal distributions are shown to highlight literature cases of exceptional thermal expansion.

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Section: Introductionmentioning

confidence: 99%

A survey of thermal expansion coefficients for organic molecular crystals in the Cambridge Structural Database

Bond¹

2021

Acta Crystallogr B Struct Sci Cryst Eng Mater

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“…15 In many instances, the NTE effect becomes more evident as a material approaches a phase transition. 16 A typical example of such a behaviour is PbTiO3 perovskite, which exhibits increasingly stronger NTE effect near its ferroelectricparaelectric phase transition. 17 NTE observed exclusively below the magnetic ordering temperature in CuO and MnF2 18 is reminiscent of the Invar effect, i.e.…”

Section: Introductionmentioning

confidence: 99%

Guest-dependent negative thermal expansion in a lanthanide-based metal–organic framework

et al. 2019

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“…The SCSC transformation phenomenon has been described in recent years for several different types of both purely organic (Centore et al, 2015;Takahashi & Tamura, 2015;Hagihara et al, 2015;Mouchaham et al, 2015;Khorasani et al, 2015) and inorganic systems (Zakharov et al, 2015;Avdeeva et al, 2015), as well as for a vast number of coordination compounds based on the combination of metal-ion centres and organic ligands that includes metal-organic frameworks (MOFs) of covalent or supramolecular nature (Neogi et al, 2014;Ren et al, 2015;Manna et al, 2015;Lee et al, 2015) and porous coordination polymers (Li et al, 2015;Coronado et al, 2012;Tahier & Oliver, 2015;Aromí et al, 2016) beyond simple Comparison between hybrid layers in the crystallographic ac plane and solvent-accessible spaces viewed along the crystallographic c axis for coordination complexes. In contrast, literature reports on SCSC transitions involving compounds that incorporate polyoxometalate (POM) clusters are comparatively much less common (Reinoso et al, 2016), despite the fact that solid-state transformations have been known for decades in POM chemistry, as exemplified by the thermally-triggered isomerization of the trilacunary [PW 9 O 34 ] 9À Keggin-type cluster from the A-form into the B-derivative (Finke et al, 1987).…”

Section: Introductionmentioning

confidence: 99%

Single-crystal-to-single-crystal transformations triggered by dehydration in polyoxometalate-based compounds

Reinoso¹,

Artetxe²,

Gutiérrez‐Zorrilla³

2018

Acta Crystallogr C Struct Chem

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Single‐crystal‐to‐single‐crystal transformations are solid‐state phase transitions between different crystalline states in which the crystal integrity and the long‐range structural order are retained through the whole transformation process. Such a phenomenon constitutes the structural response that some compounds afford when being exposed to a given external stimulus (temperature, pressure, light, etc.) and, therefore, its study has become a relevant focus of interest within crystal engineering because it allows for monitoring how certain properties (colour, magnetism, luminescence, porosity) of the stimuli‐responsive material are modified as the structure evolves into the activated form. A range of organic, inorganic and hybrid systems have been found to undergo such phase transitions, but these examples only include a small number of compounds that incorporate polyoxometalate anions, among which the removal of guest solvent molecules (dehydration) stands out as the most common external stimulus able to induce the occurrence of a single‐crystal‐to‐single‐crystal transformation. This feature article compiles the examples of dehydration‐triggered single‐crystal‐to‐single‐crystal transformation studies that have been reported to date for polyoxometalate‐based compounds and reviews some of their most relevant structural aspects.

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Low temperature phase transition induced biaxial negative thermal expansion of 2,4-dinitroanisole

Cited by 24 publications

References 43 publications

A survey of thermal expansion coefficients for organic molecular crystals in the Cambridge Structural Database

A survey of thermal expansion coefficients for organic molecular crystals in the Cambridge Structural Database

Guest-dependent negative thermal expansion in a lanthanide-based metal–organic framework

Single-crystal-to-single-crystal transformations triggered by dehydration in polyoxometalate-based compounds

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