Abstract
Uniaxial negative thermal expansion (NTE) is known to occur in low n members of the An+1BnO3n+1 Ruddlesden–Popper (RP) layered perovskite series with a frozen rotation of BO6 octahedra about the layering axis. Previous work has shown that this NTE arises due to the combined effects of a close proximity to a transition to a competing phase, so called “symmetry trapping”, and highly anisotropic elastic compliance specific to the symmetry of the NTE phase. We extend this analysis to the broader RP family (n = 1, 2, 3, 4, …, ∞), demonstrating that by changing the fraction of layer interface in the structure (i.e., the value of 1/n) one may control the anisotropic compliance that is necessary for the pronounced uniaxial NTE observed in these systems. More detailed analysis of how the components of the compliance matrix develop with 1/n allows us to identify different regimes, linking enhancements in compliance between these regimes to the crystallographic degrees of freedom in the structure. We further discuss how the perovskite layer thickness affects the frequencies of soft zone boundary modes with large negative Grüneisen parameters, associated with the aforementioned phase transition, that constitute the thermodynamic driving force for NTE. This new insight complements our previous work—showing that chemical control may be used to switch from positive to negative thermal expansion in these systems—since it makes the layer thickness, n, an additional design parameter that may be used to engineer layered perovskites with tuneable thermal expansion. In these respects, we predict that, with appropriate chemical substitution, the n = 1 phase will be the system in which the most pronounced NTE could be achieved.
Highlights
Ruddlesden–Popper (RP) oxides are an intriguing class of ceramic materials
Comparing the compliance matrices computed for different phases, we found that high anisotropic compliance is unique to the negative thermal expansion (NTE) phase of the RP structure and we linked this anisotropy to combined in-plane and out-of-plane symmetry breaking in the NTE phase
We proposed an atomic mechanism to facilitate a large compliance eigenvector in RP phases with a frozen octahedral rotation that relies on combined in-plane and out-of-plane symmetry breaking at the CaGeO3:CaO layer interface to closely couple the ab and c axes (Ablitt et al, 2017)
Summary
Ruddlesden–Popper (RP) oxides are an intriguing class of ceramic materials. They have the basic formula An+1BnO3n+1 and consist of a perovskite block of n corner sharing BO6 octahedra separated by an AO rock salt layer. While in practice most chemistries are found to predominantly exhibit the n = 1, 2 phases only (Palgrave et al, 2012), in principle any value of n between 1 and ∞ is possible; n = 3 structures have been synthesized by careful compositional control (Battle et al, 1998) and n > 3 phases are often predicted to be unstable to decomposition (McCoy et al, 1997), epitaxial growth techniques have allowed the synthesis of n = 2−5 (Haeni et al, 2001), n = 6 (Yan et al, 2011), and n = 10 (Lee et al, 2013) structures
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
