2002
DOI: 10.1002/1521-3773(20021018)41:20<3746::aid-anie3746>3.0.co;2-2
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A Concept for Synthesis Planning in Solid-State Chemistry

Abstract: There is a widely-held belief that the preparation of new solid-state compounds based on rational design is not possible. Herein, we present a concept that points the way towards a rational design of syntheses in solid-state chemistry. The foundation of our approach is the representation of the whole material world, that is, the known and not-yet-known compounds, on an energy landscape, which gives information about the free energies of these compounds. From this it follows that all chemical compounds capable … Show more

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Cited by 248 publications
(171 citation statements)
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“…While for ionic crystals the numerical proportion of the two spheres (atoms) is fixed due to charge balance, for intermetallic phases a whole range of different compositions can be probed correlating to an enormous variety of structures. Furthermore, it is well known that the very same compound can also exist in energetically less favorable modifications, so-called polymorphs [1]. However, the "disadvantages" of the model of atoms as spheres are that they are extremely small, that not every sphere size (or ratio of two sphere sizes) is available, and that the interaction cannot be adjusted for two given sphere sizes.…”
Section: Introductionmentioning
confidence: 99%
“…While for ionic crystals the numerical proportion of the two spheres (atoms) is fixed due to charge balance, for intermetallic phases a whole range of different compositions can be probed correlating to an enormous variety of structures. Furthermore, it is well known that the very same compound can also exist in energetically less favorable modifications, so-called polymorphs [1]. However, the "disadvantages" of the model of atoms as spheres are that they are extremely small, that not every sphere size (or ratio of two sphere sizes) is available, and that the interaction cannot be adjusted for two given sphere sizes.…”
Section: Introductionmentioning
confidence: 99%
“…As a result, the focus has been turned from the pure description of experimentally known compounds to the discovery of new materials by means of theoretical methods. A milestone to predict hitherto unknown compounds and structures was set by the work of Jansen, 3 emphasizing the role of theoretical methods in solid state chemistry synthesis planning. The introduction of the concept of an energy landscape that reflects the energy hypersurface of the material world and the exploration of this landscape delivers a key for rational design of syntheses.…”
Section: Introductionmentioning
confidence: 99%
“…[4] Multimetallic oxides have been known in solid-state chemistry for a long time, but the high processing temperatures typically applied make them less suitable for the preparation of nanoscaled materials. [5] In addition, optimum dispersity of the two metals inside the nanostructures would play a pivotal role for the rational synthesis and adjustment of properties of those systems. Optimum dispersity is ensured when the respective elements are distributed on the molecular level.…”
mentioning
confidence: 99%