Apparent Scarcity of Low-Density Polymorphs of Inorganic Solids

Abstract: For most inorganic solids, very few dense polymorphs and no low-density polymorphs are observed. Taking a wide range of tetrahedrally-coordinated binary solids (e.g., ZnO, GaN) as a prototypical system, we show that the apparent scarcity of low-density polymorphs is not due to significant structural or energetic limitations. Using databases of periodic networks as sources of novel crystal structures, followed by ab initio energy minimization, we predict a dense spectrum of low-density low-energy polymorphs. Th… Show more

“…It appears that the magnitude of the energy scale of metastability is similar to the strength of thermodynamic handles, suggesting that metastable structure-selection may be thermodynamic in origin, rather than kinetic. Furthermore, if the synthesis of metastable phases requires them to be stable under only some thermodynamic condition, perhaps there are no thermodynamic conditions under which our hypothetical, unobserved phases ( 12 , 16 ) are ever the lowest free-energy phases (dashed line, Fig. 3C).…”

The thermodynamic scale of inorganic crystalline metastability

“…It appears that the magnitude of the energy scale of metastability is similar to the strength of thermodynamic handles, suggesting that metastable structure-selection may be thermodynamic in origin, rather than kinetic. Furthermore, if the synthesis of metastable phases requires them to be stable under only some thermodynamic condition, perhaps there are no thermodynamic conditions under which our hypothetical, unobserved phases ( 12 , 16 ) are ever the lowest free-energy phases (dashed line, Fig. 3C).…”

The thermodynamic scale of inorganic crystalline metastability

“…7,13,14 If this picture is true, then CMPs, CTFs, PAFs, and their like, would be the closest organic polymer analogues of well-known inorganic materials such as boron nitride, zinc oxide, and (alumino)silicates, materials whose structures are also based on 3- or 4-connected networks. 15−17 Alternatively, however, these materials could also resemble highly branched polymers or dendrimers, which are tree-like molecules with a relatively large number of end-groups but, typically, no closed rings. Structural hypotheses and models 14 aside, it is essentially unknown if CMPs, CTFs, and PAFs can be best described as highly branched polymers or as extended networks, or even as small but insoluble oligomers, which might nonetheless exhibit permanent microporosity.…”

Shedding Light on Structure–Property Relationships for Conjugated Microporous Polymers: The Importance of Rings and Strain

“…However, low-pressure methods such as chemical vapour deposition could potentially enable larger scale production of Si 24 , as is the case for diamond 37 , another highpressure phase. Furthermore, the unique zeolite-like nature of this structure provides another perspective for synthesizing new lowdensity polymorphs in other classes of materials 38 , which would be of interest for gas and/or lithium storage and for molecularscale filtering applications 39 . More broadly, Si 24 expands the known allotropy in element fourteen and the novel high-pressure precursor synthesis approach suggests the potential for entirely new materials with desirable properties.…”

Synthesis of an open-framework allotrope of silicon