A Fast, Non-Destructive Test for Two-Dimensional Materials

Molecular model of a WS2 triangular monolayer targeted with a green laser (hv’). Red light (hv) is emitted from the edges where defects consisting of sulfur vacancies are located. Electron-hole pairs are bound at the vacancy site (inset).Image Credit:Yuanxi WangBy now it is well understood that thinning a material down to a single atom thickness can dramatically change that material’s physical properties. Graphene, the best known 2D material, has unparalleled strength and electrical conductivity, unlike its bulk form as graphite. Researchers have begun to study hundreds of other 2D materials for the purposes of electronics, sensing, early cancer diagnosis, water desalination, and a host of other applications. Now, a team of Penn State researchers in the Department of Physics and the Center for Two-Dimensional and Layered Materials (2DLM) has developed a fast, nondestructive optical method for analyzing defects in two-dimensional materials.

“In the semiconductor industry, for example, defects are important because you can control properties through defects,” said Mauricio Terrones, professor of physics, materials science, and engineering and chemistry, Penn State. “This is known as defect engineering. Industry knows how to control defects and which types are good for devices.”

To really understand what is going on in a 2D material like tungsten disulfide, which has a single atom-thick layer of tungsten sandwiched between two atomic layers of sulfur, would require a high-power electron microscope capable of seeing individual atoms and the holes, called vacancies, where the atoms are missing.

“The benefit of transmission electron microscopy (TEM) is that you get an image and you can see directly what is going on—you get direct evidence,” said Bernd Kabius, staff scientist at Penn State’s Materials Research Institute, an expert in TEM and a coauthor on the paper appearing April 28 in the online journal Science Advances.

The downsides, according to Kabius, are an increased possibility of damage to the delicate 2D material, the complex preparation required of the sample and the time involved—an entire day of instrument time to image a single sample and a week or more to interpret the results. For those reasons, and others, researchers would like to combine TEM with another method of looking at the sample that is simpler and faster.

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The technique developed by Terrones and his team uses an optical method, fluorescent microscopy, in which a laser of a specific wavelength is shone on a sample and the excited electrons, pushed to a higher energy level, each emit a photon of a longer wavelength when the electron drops down to a lower energy level. The wavelength, or color of light, can be measured by spectroscopy and gives information about the defect type and location on the sample. This data shows up as peaks on a graph, which the team then correlated to visual confirmation under the TEM. Theoretical calculations also helped to validate the optical results. A necessary step in the process requires placing the sample in a temperature-controlled specimen holder, or stage, and lowering the temperature to 77 kelvin, almost 200 degrees C below zero. At this temperature, the electron-hole pairs that produce the fluorescence are bound to the defect—in the case of this work a group of sulfur vacancies in the top layer of the sandwich—and emit a signal stronger than the pristine areas of the material.

Terrones added, “For the semiconductor industry, this is a quick measurement, an optical nondestructive method to evaluate defects in 2D systems. The important thing is that we were able to correlate our optical method with TEM and also with atomistic simulations. I think this method can be very helpful in establishing a protocol for characterization of 2D crystalline materials.”

In this context, co-author Yuanxi Wang, a postdoctoral researcher in the 2DLM and a theorist, added, “Our calculations show that electrons trapped by vacancies emit light at wavelengths different than the emission from defect-free regions. Regions emitting light at these wavelengths can easily identify vacancies within samples.”

And Vincent Crespi, distinguished professor of physics, materials science, and engineering and chemistry, Penn State, said “We can establish not just an empirical correlation between the presence of certain defects and modified light emission, but also identify the reason for that correlation through first-principles calculations.”

Device applications that could be enhanced by this work include membranes with selective pore sizes for removing salt from water or for DNA sequencing, gas sensing when gas molecules bind to specific vacancies and the doping of 2D materials, which is the addition of foreign atoms to enhance properties.  

In addition to Terrones, Carozo, Wang, Kabius, and Crespi, authors on the Science Advances paper, titled “Optical Identification of Sulfur Vacancies: Bound Excitons at the Edges of Monolayer Tungsten Disulfide,” are  postdoctoral scholars Kazunori Fujisawa, Bruno Carvalho and Amber McCreary; PhD students Simin Feng, Zhong Lin, and Chanjing Zhou; research associates Nestor Perea-Lopez and Ana Laura Elias.  All of the work was performed at Penn State.

The work was supported by the National Science Foundation and the U.S. Army Research Office.