Abstract
This paper develops a statistical learning approach to identify potentially new high-temperature ferroelectric piezoelectric perovskite compounds. Unlike most computational studies on crystal chemistry, where the starting point is some form of electronic structure calculation, we use a data-driven approach to initiate our search. This is accomplished by identifying patterns of behaviour between discrete scalar descriptors associated with crystal and electronic structure and the reported Curie temperature (TC) of known compounds; extracting design rules that govern critical structure–property relationships; and discovering in a quantitative fashion the exact role of these materials descriptors. Our approach applies linear manifold methods for data dimensionality reduction to discover the dominant descriptors governing structure–property correlations (the ‘genes’) and Shannon entropy metrics coupled to recursive partitioning methods to quantitatively assess the specific combination of descriptors that govern the link between crystal chemistry and TC (their ‘sequencing’). We use this information to develop predictive models that can suggest new structure/chemistries and/or properties. In this manner, BiTmO3–PbTiO3 and BiLuO3–PbTiO3 are predicted to have a TC of 730°C and 705°C, respectively. A quantitative structure–property relationship model similar to those used in biology and drug discovery not only predicts our new chemistries but also validates published reports.
Highlights
Through many seminal papers, Alan McKay has expounded on the idea of a framework for ‘Generalized Crystallography’ (Mackay 1966, 1974, 1977, 1986)
Structure–property relationships are guided by defined functional relationships
We have applied this approach to explore a variety of questions associated with crystal chemistry (Suh & Rajan 2005, 2009; Gadzuric et al 2006; Rajagopalan & Rajan 2007; George et al 2009; Broderick et al 2010; Rajan 2010, Zenasni et al 2010), and in this paper, we demonstrate that by using the QSPR concept, we can identify through the tools of statistical inference, how discrete bits of information that define a robust QSPR relationship can be sequenced to help identify new materials with new and targeted properties
Summary
Alan McKay has expounded on the idea of a framework for ‘Generalized Crystallography’ (Mackay 1966, 1974, 1977, 1986). He went on to suggest that these components of description of structure can help develop a ‘biological approach to inorganic systems’ and proposed the construction of an ‘inorganic gene’ This paradigm serves as motivation underlying the present study by exploring how fundamental pieces of information, treated as discrete bits of data, can collectively characterize the stability and properties of a given crystal chemistry. We extract design rules that allow us to systematically identify critical structure–property relationships, resulting in identifying in a quantitative fashion the exact role of specific combination of materials descriptors (i.e. genes) that govern a given property This is the foundation of the concept of the quantitative structure–activity (or property) relationship (QSAR/QSPR) widely used in the field of organic chemistry and drug discovery. This paper serves as a generic template for an information science-based materials discovery and design strategy, in the spirit of Mackay’s proposition of an inorganic gene
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