Open AccessSubtle polymorphism of zinc imidazolate frameworks: temperature-dependent ground states in the energy landscape revealed by experiment and theory
Author(s) -
Christian Schröder,
Igor A. Baburin,
Leo van Wüllen,
Michael Wiebcke,
Stefano Leoni
Publication year - 2012
Publication title -
crystengcomm
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.813
H-Index - 132
ISSN - 1466-8033
DOI - 10.1039/c2ce26045j
Subject(s) - metastability , differential scanning calorimetry , zinc , zeolitic imidazolate framework , polymorphism (computer science) , diffraction , phase transition , density functional theory , crystallography , topology (electrical circuits) , materials science , crystallization , phase (matter) , imidazolate , thermodynamics , chemical physics , chemistry , metal organic framework , computational chemistry , physics , inorganic chemistry , mathematics , biochemistry , organic chemistry , adsorption , combinatorics , gene , genotype , optics , metallurgy
We show by variable-temperature X-ray diffraction and differential scanning calorimetry experiments that zinc imidazolates with coi and zni framework topology, respectively represent the thermodynamically stable phase below and above a transition temperature of ≈360 °C at ambient pressure. The relative stability of the two polymorphs and the experimentally observed strong negative thermal expansion of the coi phase at high temperatures close to the phase transition were successfully modelled using density functional theory calculations. A novel metastable zinc imidazolate with neb framework topology was detected by in situ X-ray diffraction experiments as a transient crystalline phase during solvothermal crystallisation of the stable coi phase
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