Cervantes

Hoy es el día más hermoso de nuestra vida, querido Sancho; los obstáculos más grandes, nuestras propias indecisiones; nuestro enemigo más fuerte, el miedo al poderoso y a nosotros mismos; la cosa más fácil, equivocarnos; la más destructiva, la mentira y el egoísmo; la peor derrota, el desaliento; los defectos más peligrosos, la soberbia y el rencor; las sensaciones más gratas, la buena conciencia, el esfuerzo para ser mejores sin ser perfectos, y sobretodo, la disposición para hacer el bien y combatir la injusticia dondequiera que esté.

MIGUEL DE CERVANTES
Don Quijote de la Mancha.
La Colmena no se hace responsable ni se solidariza con las opiniones o conceptos emitidos por los autores de los artículos.

31 de octubre de 2017

Understanding how electrons turn to glass

by Staff WritersSendai, Japan (SPX) Oct 26, 2017


Electrons transition from a liquid state (top) to a glassy state (bottom) upon cooling.

Researchers at Tohoku University have gained new insight into the electronic processes that guide the transformation of liquids into a solid crystalline or glassy state.
The ability of some liquids to transition into glass has been exploited since ancient times. But many fundamental aspects of this transition phase are far from understood. Better understanding could spur the development of new products, such as DVDs or blue ray discs that store data by altering their state of matter from one to another, and of new glass materials.
A multi-institutional Japanese team, led by Kenichiro Hashimoto of Tohoku University's Institute for Materials Research, compared the molecular dynamics of glass formation in conventional liquids, such as glucose, to an organic metal material containing 'frustrated' electrons. These electrons, responsible for conducting electrical currents, are unable to reach their lowest energy state due to the way they are geometrically arranged on the material's crystal lattice.
Slow cooling of conventional glass-forming liquids causes their atoms to organize themselves into regular arrangements, producing a crystallized material. When the researchers slowly cooled the organic metal they were testing, its frustrated electrons similarly organized into a regular pattern and crystallized. However, when the material was cooled more quickly, crystallization was avoided and the material's frustrated electrons re-organized, turning into glass in a similar manner to conventional glass-forming liquids.
The results highlight the universal nature of the liquid-to-glass transition phase.
The researchers believe their organic metal provides a convenient test platform for studying the fundamental properties of the liquid-to-glass transition.