David Keen

Observation of a Reversible Order‐Order Transition in a Metal‐Organic Framework – Ionic Liquid Nanocomposite Phase‐Change Material

Small Wiley 20:43 (2024) e2303315

Authors:

Vahid Nozari, Ayda Nemati Vesali Azar, Roman Sajzew, Celia Castillo‐Blas, Ayano Kono, Martin Oschatz, David A Keen, Philip A Chater, Georgina P Robertson, James MA Steele, Luis León‐Alcaide, Alexander Knebel, Christopher W Ashling, Thomas D Bennett, Lothar Wondraczek

Author Correction: Resolving length-scale-dependent transient disorder through an ultrafast phase transition

Nature Materials Springer Nature 23:8 (2024) 1150-1150

Authors:

Jack Griffiths, Ana F Suzana, Longlong Wu, Samuel D Marks, Vincent Esposito, Sébastien Boutet, Paul G Evans, JF Mitchell, Mark PM Dean, David A Keen, Ian Robinson, Simon JL Billinge, Emil S Bozin

Resolving length-scale-dependent transient disorder through an ultrafast phase transition

Nature Materials Springer Nature 23:8 (2024) 1041-1047

Authors:

Jack Griffiths, Ana F Suzana, Longlong Wu, Samuel D Marks, Vincent Esposito, Sébastien Boutet, Paul G Evans, JF Mitchell, Mark PM Dean, David A Keen, Ian Robinson, Simon JL Billinge, Emil S Bozin

Loading and thermal behaviour of ZIF-8 metal–organic framework-inorganic glass composites

Dalton Transactions Royal Society of Chemistry (RSC) 53:25 (2024) 10655-10665

Authors:

Ashleigh M Chester, Celia Castillo-Blas, Roman Sajzew, Bruno P Rodrigues, Giulio I Lampronti, Adam F Sapnik, Georgina P Robertson, Matjaž Mazaj, Daniel JM Irving, Lothar Wondraczek, David A Keen, Thomas D Bennett

Local Structure and Dynamics in MPt(CN) 6 Prussian Blue Analogues

Chemistry of Materials American Chemical Society 36:11 (2024) 5796-5804

Authors:

Elodie A Harbourne, Helena Barker, Quentin Guéroult, John Cattermull, Liam AV Nagle-Cocco, Nikolaj Roth, John SO Evans, David A Keen, Andrew L Goodwin

Abstract:

We use a combination of X-ray pair distribution function (PDF) measurements, lattice dynamical calculations, and ab initio density functional theory (DFT) calculations to study the local structure and dynamics in various MPt­(CN)6 Prussian blue analogues. In order to link directly the local distortions captured by the PDF with the lattice dynamics of this family, we develop and apply a new “interaction-space” PDF refinement approach. This approach yields effective harmonic force constants, from which the (experiment-derived) low-energy phonon dispersion relations can be approximated. Calculation of the corresponding Grüneisen parameters allows us to identify the key modes responsible for negative thermal expansion (NTE) as arising from correlated tilts of coordination octahedra. We compare our results against the phonon dispersion relations determined using DFT calculations, which identify the same NTE mechanism.