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| title | chunk | source | category | tags | date_saved | instance |
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| Chemical crystallography before X-rays | 4/6 | https://en.wikipedia.org/wiki/Chemical_crystallography_before_X-rays | reference | science, encyclopedia | 2026-05-05T16:17:25.610345+00:00 | kb-cron |
== Polymorphism ==
In crystallography, polymorphism is the phenomenon where a compound can crystallize into more than one crystal structure; in the case of elements the term allotropy is sometimes used. An example of polymorphism is titanium dioxide (TiO2), which occurs in four known natural polymorphic forms (minerals with the same composition but different structure): brookite (orthorhombic), akaogiite (monoclinic), anatase (tetragonal) and rutile (tetragonal). Eilhard Mitscherlich discovered polymorphism ("dimorphism") in his studies of sodium phosphate (1821) and sulphur (1823). In the 1830s the development of the microscope enhanced observations of polymorphism and aided Moritz Ludwig Frankenheim's studies. Frankenheim was able to demonstrate methods to induce crystal phase changes, for example the use of solvents or physical scratching, and formally summarized his findings on the nature of polymorphism. Soon after, the more sophisticated polarized light microscope came into use, and it provided better visualization of crystalline phases allowing crystallographers to distinguish between different polymorphs. The hot stage was invented and fitted to a polarized light microscope by Otto Lehmann in about 1877. This invention helped crystallographers determine melting points and observe polymorphic transitions. The first polymorphic organic substance, benzamide, was discovered by Friedrich Wöhler and Justus von Liebig in 1832. In 1870 Paul Groth defined wikt:morphotropy as the state of two crystals whose similar physical structure is due to similar chemical composition. Groth examined the change in symmetry of a crystal as a result of the replacement of a hydrogen atom by another univalent atom or radical. Morphotropy is also referred to as isogonism in which each vertex is surrounded by the same kinds of face in the same or reverse order, and with the same angles between corresponding faces. In 1897 Wilhelm Ostwald introduced Ostwald's rule, to describe the formation of polymorphs. The rule states that usually the less stable polymorph crystallizes first. Ostwald's rule is not a universal law but a common tendency observed in nature.
== Molecular chirality ==
In 1811 François Arago constructed a polariscope and used it to discover that quartz crystals would rotate the plane of polarization of polarized light. Shortly after Jean-Baptiste Biot found a similar optical rotation effect for solutions, for example tartaric acid, and concluded that the effect was a inherent property of certain molecules. In 1830 Jöns Jacob Berzelius discovered that tartaric and racemic acids have the same elementary composition, and concluded that a difference in the arrangement of the atoms in the molecules creates compounds with different chemical properties; in the same paper Berzelius suggested the term "isomerism" for the phenomenon. In 1831 Mitscherlich was asked by Berzelius to study the tartrates in order to determine the differences between two isomers, tartaric acid and racemic acid. By 1832, Jean-Baptiste Biot had discovered that tartaric acid from grape juice was dextrorotatory and that racemic acid was optically inactive. In 1844 Mitscherlich found that the solution of sodium ammonium tartrate was optically active, but that of sodium ammonium paratartrate was optically inactive. The work of Biot and Mitscherlich was the starting point for research by the French chemist Louis Pasteur, a doctoral student of Gabriel Delafosse and a colleague of Auguste Laurent. In 1848 Louis Pasteur gave the general relation between crystal morphology and rotatory polarization. Pasteur solved the mystery of polarized light acting differently with chemically identical crystals and solutions by discovering the phenomenon of molecular asymmetry, that is that molecules could be chiral and exist as a pair of enantiomers. Pasteur's method was to physically separate the crystals of a racemic mixture of sodium ammonium tartrate into right- and left-handed crystals, and then dissolve them to make two separate solutions which rotated polarized light in opposite directions. Pasteur's research was in part informed by considerations of molecular symmetry. Pasteur also proposed two other methods for the isolation of optically active enantiomers from racemic mixtures: by the use of optically active bases, e.g. strychnine, or by means of living organisms, e.g. bacteria or yeasts. William Thomson (Lord Kelvin) introduced the word "chiral" in 1904 to describe handed figures. Objects that do not exhibit optical isomerism are said to be "achiral", that is their image in a plane mirror can be made congruent with itself. The term chirality has almost completely displaced the term "dissymmetry" which was used by Pasteur.
== Liquid crystals ==