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Shaping nanoparticles for improved quantum information technology

Breaking of rotational symmetry in ring-shaped nanoparticle leads to surprising quantum property when illuminated with laser.

Artistic rendering of semiconductor quantum rings being illuminated by a laser and emitting single photons

Artistic rendering of semiconductor quantum rings being illuminated by a laser and emitting single photons. (Image by Argonne National Laboratory.)

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OCTOBER 10, 2019

BY JOSEPH E. HARMON

Particles that are mere nanometers in size are at the forefront of scientific research today. They come in many different shapes: rods, spheres, cubes, vesicles, S-shaped worms and even donut-like rings. What makes them worthy of scientific study is that, being so tiny, they exhibit quantum mechanical properties not possible with larger objects.

Researchers at the Center for Nanoscale Materials (CNM), a U.S. Department of Energy (DOE) Office of Science User Facility located at DOE’s Argonne National Laboratory, have contributed to a recently published Nature Communications paper that reports the cause behind a key quantum property of donut-like nanoparticles called “semiconductor quantum rings.”  This property may find application in quantum information storage, communication, and computing in future technologies.

“If you illuminate a two-dimensional photon emitter with a laser, you expect them to emit light along two axes, but what you expect is not necessarily what you get. To our surprise, these two-dimensional rings can emit light along one axis.” — Xuedan Ma, assistant scientist, Center for Nanoscale Materials

In this project, the CNM researchers collaborated with colleagues from the University of Chicago, Ludwig Maximilian University of Munich, University of Ottawa and National Research Council in Canada.

The team assembled circular rings made out of cadmium selenide, a semiconductor that lends itself to growing donut-shaped nanoparticles. These quantum rings are two-dimensional structures — crystalline materials composed of a few layers of atoms. The advantage of semiconductors is that when researchers excite them with a laser, they emit photons.

“If you illuminate a two-dimensional photon emitter with a laser, you expect them to emit light along two axes,” said Xuedan Ma, assistant scientist at CNM. “But what you expect is not necessarily what you get. To our surprise, these two-dimensional rings can emit light along one axis.”

The team observed this effect when breaking the perfect rotational symmetry of the donut shape, causing them to be slightly elongated. “By this symmetry breaking,” says Ma, “we can change the direction of light emission. We can thus control how photons come out of the donut and achieve coherent directional control.”

Because the photons in the light emits from these rings along a single direction, rather than spreading out in all directions, researchers can tune this emission to effectively collect single photons. With this control, researchers can integrate topology information into the photons, which can then be used as messengers for carrying quantum information. It may even be possible to exploit these encoded photons for quantum networking and computation.

“If we can gain even greater control over the fabrication process, we could make nanoparticles with different shapes such as a clover with multiple holes or a rectangle with a hole in the center,” noted Matthew Otten, a Maria Goeppert Mayer Fellow at Argonne’s CNM. “Then, we might be able to encode more types of quantum information or more information into the nanoparticles.”

“I should add that geometry is not the only factor in causing this quantum effect. The atomistic structure of the material also counts, as is often the case in nanoscale materials,” said Ma.

A paper based on the study, ​“Uniaxial transition dipole moments in semiconductor quantum rings caused by broken rotational symmetry,” appeared recently in Nature Communications. In addition to Ma and Otten, authors include Nicolai F. Hartmann, Igor Fedin, Dmitri Talapin, Moritz Cygorek, Pawel Hawrylak, Marek Korkusinski, Stephen Gray and Achim Hartschuh.

This work was supported by the DOE Office of Science.












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