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Materials

Slow And Steady Makes Perfect Crystals

Cooling DNA-tagged nanoparticles a few degrees over the course of days drives crystallization toward theoretically predicted geometry

by Mitch Jacoby
December 2, 2013 | A version of this story appeared in Volume 91, Issue 48

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Credit: Evelyn Auyeung/Ting Li/Chad A. Mirkin/Monica Olvera de la Cruz
An SEM image of a crystal. Inset, fuzzy spheres tightly packed.
Credit: Evelyn Auyeung/Ting Li/Chad A. Mirkin/Monica Olvera de la Cruz

It’s not hard to be a perfectionist if you have all the time in the world to do a job right. Guided by that thinking, Northwestern University’s Evelyn Auyeung, Monica Olvera de la Cruz, Chad A. Mirkin, and coworkers have shown that metal nanoparticles tagged with strands of DNA can be coaxed into assembling nearly perfect crystals with predictable geometries simply by cooling the system from a little above to a little below its melting point over the course of several days (Nature 2013, DOI: 10.1038/nature12739). That finding may lead to custom-designed crystals for photonics, electronics, and catalysis applications. Atoms form crystals by way of fairly well understood processes. Not so for molecules and large particles. Previous attempts to use DNA base-pair recognition to form nanoparticle crystals led to ill-formed crystals or ones with unexpected geometries that varied with nanoparticle size. In contrast, the slow-cooling method leads to micrometer-sized faceted crystals with a rhombic dodecahedron shape (shown, with inset rendering of DNA-tagged nanoparticles) regardless of nanoparticle size. That outcome is the thermodynamically favored and theoretically predicted one, the team notes.

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