Abstract
Helical conformations and structures are frequently observed in materials. The presence of helices at points of the unit cell of a crystal, on a larger size scale in the crystalline lattice or even in the microscopic structure of crystals, affects the chemico-physical properties of a solid and, hence, also interactions with light. Here, attention has been drawn to the geometrical properties of helices produced by a hypothetical torque of a transparent crystal, and optical properties of twisted crystals easily observed by a polarizing microscope have been discussed. Radially grown spherulites are obtained by most substances crystallized from melt. The circular arrangement of elongated crystals reflects the optical behaviour of each crystal and, because of the larger dimensions of spherulites, allows investigations otherwise hardly feasible on separate crystals. According to the torsional analysis of elongated bodies and the birefringence theory, information on the existence of helically shaped crystals can be deduced, as hereinafter explained, from the microscopic appearance and birefringence pattern of spherulites. Indeed, twisting decreases the birefringence throughout an elongated crystal and, therefore, also the birefringence of spherulites formed by twisted radial crystals is reduced.
Highlights
An exhaustive analysis of the interaction of matter with light is fundamental for the achievement of technological advances and innovations
The X-ray pattern and the optical behaviour of quartz evidence the presence, along the c axis, of helical conformation of SiO4 tetrahedrons sharing corners [2,3,4,5]. Banding such as that occasionally observed in some samples of cryptocrystalline fibres of SiO2 has been ascribed to alternate twisted and untwisted growth during crystallization [6], whereas twinning has been claimed to be responsible for banding in potassium chlorate crystals, where the periodical variation of the direction of the optic axis causes bright and dark bands when the crystal is viewed between crossed Nicol prisms [1]
Notwithstanding a few authors ascribed banding in polymers to cooperative twisting of radial crystals in spherulites, other investigators observed that it is topologically impossible to arrange in such a way a set of ribbons [28]
Summary
Cite this article: Raimo M. 2019 An optical test to unveil twisting of birefringent crystals in spherulites. 2019 An optical test to unveil twisting of birefringent crystals in spherulites.
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