Collective Buckling in Metal-Organic Framework Materials
Authors
Nico Hahn, Lars Öhrström, R. Matthias Geilhufe
Categories
Abstract
We develop a framework to describe collective buckling in metal-organic frameworks (MOFs). Starting from the microscopic structure of a single organic linker, we define a buckling coordinate governed by an effective double-well potential. Coupling between linkers arises from dipole-dipole interactions, leading to a lattice Hamiltonian. We analyze the transition between ordered and disordered phases within a mean-field approximation and determine the critical temperature. As an example for our theory, we discuss the collective buckling instability for the prototypical cubic framework MOF-5 under different values of uniaxial strain. Our approach enables a quantitative description of collective buckling in framework materials.
Collective Buckling in Metal-Organic Framework Materials
Categories
Abstract
We develop a framework to describe collective buckling in metal-organic frameworks (MOFs). Starting from the microscopic structure of a single organic linker, we define a buckling coordinate governed by an effective double-well potential. Coupling between linkers arises from dipole-dipole interactions, leading to a lattice Hamiltonian. We analyze the transition between ordered and disordered phases within a mean-field approximation and determine the critical temperature. As an example for our theory, we discuss the collective buckling instability for the prototypical cubic framework MOF-5 under different values of uniaxial strain. Our approach enables a quantitative description of collective buckling in framework materials.
Authors
Nico Hahn, Lars Öhrström, R. Matthias Geilhufe
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