Skip to Main Content

Latest News

May 21, 2007
Volume 85, Number 21
p. 5

Polymeric Quasicrystals

Materials Science: Organic materials join ranks with alloys and other aperiodic, ordered structures

Mitch Jacoby

Courtesy of Atsushi Takano (both)
View Enlarged Image
Connecting the key features of an electron micrograph of a polymer blend creates a pattern of irregular squares and triangles that reveals the material's quasicrystalline order and 12-fold rotational symmetry (above). Those features are more pronounced when the pattern is composed of regular shapes (below).
View Enlarged Image

Adding to a short but growing list of materials that form quasicrystals, researchers in Japan have discovered that organic polymers can assemble into the aperiodic geometries that characterize this unusual class of ordered structures. The study broadens understanding of polymeric systems and may stimulate further research in noncrystalline ordered materials.

In the current work, Kenichi Hayashida, Atsushi Takano, and Yushu Matsushita of Nagoya University's department of applied chemistry, along with condensed matter physicist Tomonari Dotera of Kyoto University, have demonstrated that certain blends of polyisoprene, polystyrene, and poly(2-vinylpyridine) form star-shaped copolymers that assemble into quasicrystals. By probing the samples with transmission electron microscopy and X-ray diffraction methods, the team concludes that the films are composed of aperiodic patterns of triangles and squares that exhibit 12-fold symmetry???telltale signs of quasicrystalline ordering (Phys. Rev. Lett. 2007, 98, 195502).

These newly discovered organic, or soft, quasicrystals not only provide "exciting alternative experimental platforms" for the basic study of quasiperiodic long-range order but also hold the promise for new applications, comments Ron Lifshitz, an associate professor of physics at Tel Aviv University. For example, soft quasicrystals might be used as photonic crystals, which control the propagation of light waves, thereby broadening the range of light that photonic crystals control selectively.

The classic definition of crystallinity is built upon periodicity—the idea that crystals are composed of geometric patterns of atoms that repeat in three dimensions at fixed intervals. Unlike conventional crystals, quasicrystals lack periodic structures yet are well-ordered, as indicated by the sharp diffraction patterns they generate. Quasicrystals also differ from ordinary crystals in another fundamental way: They exhibit rotational symmetries (often fivefold or 10-fold) that are forbidden according to conventional crystallography.

Since the discovery of aluminum-based quasicrystals in the 1980s, scientists have been engaged in lively debates regarding the nature and atomic structure of the unusual materials. Basic questions regarding their structures remain unanswered. Even so, quasicrystals have found their way into commercial products that exploit the materials' hardness and thermal properties. Examples include nonstick scratch-resistant coatings for high-end cookware and hardeners for steel used in electric razors and other tools.

In addition to aluminum-based quasicrystals, other intermetallic alloys were also found to exhibit quasicrystal structures. Eventually, other classes of materials, including chalcogenides such as tantalum telluride and dendrimer-based liquid crystals were added to the list. Now, the list has grown again as organic polymers have joined the ranks of quasicrystals.

Lifshitz adds that the study of soft quasicrystals is likely to promote fundamental understanding of quasicrystals. Fortunately, these findings are coming at a time when the science of quasicrystals is mature enough to tackle these newly discovered systems, he says. "We are no longer taken by surprise whenever a new chemical or physical system exhibits quasicrystalline structure. We are prepared with the appropriate tools to study and explore it."

Chemical & Engineering News
ISSN 0009-2347
Copyright © 2011 American Chemical Society