Energy-momentum spectroscopy improves thin-film materials analysis

Providence, RI--A multi-university research team including Brown University researchers used a new spectroscopic method (http://www.laserfocusworld.com/spectroscopy.html) to gain a key insight into how light is emitted from layered nanomaterials and other thin films. The method, called energy-momentum spectroscopy (http://www.laserfocusworld.com/articles/print/volume-48/issue-10/features/spectrometers-chip-based-resonant-spectroscopy-overcomes-traditional-challenges.html), enables researchers to look at the light emerging from a thin film and determine whether it is coming from emitters oriented along the plane of the film or from emitters oriented perpendicular to the film. Knowing the orientations of emitters could help engineers make better use of thin-film materials in optical devices like LEDs or solar cells.

The published Nature Nanotechnology research was a collaborative effort of Brown University, Case Western Reserve University (Cleveland, OH), Columbia University (New York, NY), and the University of California, Santa Barbara.

The new technique takes advantage of a fundamental property of thin films: interference. Interference effects can be seen in the rainbow colors visible on the surface of soap bubbles or oil slicks. Scientists can analyze how light constructively and destructively interferes at different angles to draw conclusions about the film itself. This new technique takes that kind of analysis one step further for light-emitting thin films.

"The key difference in our technique is we're looking at the energy as well as the angle and polarization at which light is emitted," said Rashid Zia, assistant professor of engineering at Brown University and one of the study's lead authors. "We can relate these different angles to distinct orientations of emitters in the film. At some angles and polarizations, we see only the light emission from in-plane emitters, while at other angles and polarizations we see only light originating from out-of-plane emitters."

The researchers demonstrated their technique on two important thin-film materials, molybdenum disulfide (MoS₂; similar to graphene) and PTCDA (an organic semiconductor). The research showed that light emission from MoS₂ occurs only from in-plane emitters. In PTCDA, light comes from two distinct species of emitters, one in plane and one out of plane.

Once the orientation of the emitters is known, Zia says, it may be possible to design structured devices that maximize those directional properties. In most applications, thin-film materials are layered on top of each other. The orientations of emitters in each layer indicate whether electronic excitations are happening within each layer or across layers, and that has implications for how such a device should be configured. The same concept could apply to light-absorbing devices like solar cells. By understanding how the electronic excitations happen in the material, it could be possible to structure it in a way that coverts more incoming light to electricity.

"One of the exciting things about this research is how it brought together people with different expertise," Zia said. "Our group's expertise at Brown is in developing new forms of spectroscopy and studying the electronic origin of light emission. The Kymissis group at Columbia has a great deal of expertise in organic semiconductors, and the Shan group at Case Western has a great deal of expertise in layered nanomaterials. Jon Schuller, the study's first author, did a great job in bringing all this expertise together. Jon was a visiting scientist here at Brown, a postdoctoral fellow in the Energy Frontier Research Center at Columbia, and is now a professor at UCSB."

SOURCE: Brown University; http://news.brown.edu/pressreleases/2013/03/spectroscopy