David Keen

Structure and properties of an amorphous metal-organic framework.

Physical review letters 104:11 (2010) 115503

Authors:

Thomas D Bennett, Andrew L Goodwin, Martin T Dove, David A Keen, Matthew G Tucker, Emma R Barney, Alan K Soper, Erica G Bithell, Jin-Chong Tan, Anthony K Cheetham

Abstract:

ZIF-4, a metal-organic framework (MOF) with a zeolitic structure, undergoes a crystal-amorphous transition on heating to 300 degrees C. The amorphous form, which we term a-ZIF, is recoverable to ambient conditions or may be converted to a dense crystalline phase of the same composition by heating to 400 degrees C. Neutron and x-ray total scattering data collected during the amorphization process are used as a basis for reverse Monte Carlo refinement of an atomistic model of the structure of a-ZIF. The structure is best understood in terms of a continuous random network analogous to that of a-SiO2. Optical microscopy, electron diffraction and nanoindentation measurements reveal a-ZIF to be an isotropic glasslike phase capable of plastic flow on its formation. Our results suggest an avenue for designing broad new families of amorphous and glasslike materials that exploit the chemical and structural diversity of MOFs.

Preface: Symposium HH

Materials Research Society Symposium Proceedings 1184 (2009)

Authors:

F Bridges, DA Keen, I Levin, T Proffen

Magnetic order and dynamics of the charge-ordered antiferromagnet La1.5Sr0.5CoO4

Physical Review B American Physical Society (APS) 80:13 (2009) 134414

Authors:

LM Helme, AT Boothroyd, R Coldea, D Prabhakaran, CD Frost, DA Keen, LP Regnault, PG Freeman, M Enderle, J Kulda

Topologically ordered amorphous silica obtained from the collapsed siliceous zeolite, silicalite-1-F: a step toward "perfect" glasses.

Journal of the American Chemical Society 131:34 (2009) 12333-12338

Authors:

Julien Haines, Claire Levelut, Aude Isambert, Philippe Hébert, Shinji Kohara, David A Keen, Tahar Hammouda, Denis Andrault

Abstract:

A dense amorphous form of silica was prepared at high pressure from the highly compressible, siliceous zeolite, silicalite-1-F. Reverse Monte Carlo modeling of total X-ray scattering data shows that the structure of this novel amorphous form of SiO(2) recovered under ambient conditions is distinct from vitreous SiO(2) and retains the basic framework topology (i.e., chemical bonds) of the starting crystalline zeolite. This material is, however, amorphous over the different length scales probed by Raman and X-ray scattering due to strong geometrical distortions. This is thus an example of new topologically ordered, amorphous material with a different intermediate-range structure, a lower entropy with respect to a standard glass, and distinct physical and mechanical properties, eventually approaching those of an "ordered" or "perfect" glass. The same process in more complex aluminosilicate zeolites will, in addition, lead to an amorphous material which conserves the framework topology and chemical order of the crystal. The large volume collapse in this material may also be of considerable interest for new applications in shock wave absorption.

Effect of Ga Content on the Instantaneous Structure of Al(1−x)Ga x PO4 Solid Solutions at High Temperature

Chemistry of Materials American Chemical Society (ACS) 21:2 (2009) 237-246

Authors:

Olivier Cambon, Julien Haines, Martine Cambon, David A Keen, Matthew G Tucker, Laurent Chapon, Niels K Hansen, Mohamed Souhassou, Florence Porcher