By Scott Gibson, Oak Ridge National Laboratory October 10, 2024

Collected at: https://scitechdaily.com/revolutionary-technology-unlocks-quantum-material-secrets-at-atomic-level/

Oak Ridge National Laboratory’s new RODAS technology provides detailed insights into atomic changes in materials, critical for advancing quantum computing.

The method’s ability to analyze materials like molybdenum disulfide without damaging them marks a significant improvement over traditional techniques, offering potential breakthroughs in material science.

A team of researchers led by the Department of Energy’s Oak Ridge National Laboratory has developed a novel method for observing changes in materials at the atomic level. This technique opens new avenues for advancing our understanding and development of materials critical for quantum computing and electronics.

Breakthrough in Quantum Material Analysis

Dubbed the Rapid Object Detection and Action System, or RODAS, this technique merges imaging, spectroscopy, and microscopy to capture the properties of fleeting atomic structures as they form. This provides unparalleled insights into the evolution of material properties at the smallest scales.

Traditional approaches combining scanning transmission electron microscopy, or STEM, with electron energy loss spectroscopy, or EELS, have been limited because the electron beam can change or degrade the materials being analyzed. That dynamic often causes scientists to measure altered states rather than the intended material properties. RODAS overcomes the limitation and also integrates the system with dynamic computer-vision-enabled imaging, which uses real-time machine learning.

Performing Electron Microscopy Measurements Using Deep Learning
Electron microscopy measurements are usually performed by collecting all points in a 2D grid. Here, using deep learning in real time, only sites of interest are measured (colored circles), allowing experiments to be conducted on a much larger variety of materials, even those that change under the beam. Credit: Kevin Roccapriore and Scott Gibson/ORNL, U.S. Dept. of Energy

Rapid and Non-Destructive Testing

When analyzing the specimen, RODAS focuses only on areas of interest. This approach enables rapid analysis — in seconds or milliseconds — compared with sometimes several minutes that can be required by other STEM-EELS methods. Importantly, RODAS extracts crucial information without destroying the sample.

All materials have defects, and these defects can directly influence virtually any of a material’s properties — whether electronic, mechanical or quantum, for example. Defects can arrange themselves in a variety of ways at the atomic level, both intrinsically and in response to external stimuli, such as electron beam irradiation. Unfortunately, the local properties of these various defect configurations are not well understood. Although STEM methods can experimentally measure such configurations, investigating specific configurations without altering them is extremely challenging. 

“Understanding defect configurations is crucial for developing next-generation materials,” said the study’s lead author, Kevin Roccapriore of ORNL’s Center for Nanophase Materials Sciences. “If empowered with that knowledge, we could intentionally create a specific configuration to produce a specific property. Such work is entirely separate from the observation and analysis activity but represents one potentially impactful direction for the future.” 

Unleashing Quantum Materials’ Potential

The research team demonstrated their technique on single-layer molybdenum disulfide, a promising semiconductor material for quantum computing and optics applications. Molybdenum disulfide is particularly interesting because it can emit single photons from defects known as single sulfur vacancies. In this material, a single sulfur vacancy refers to the absence of one sulfur atom from its honeycombed lattice structure, which is the arrangement of the atoms. These vacancies can aggregate, creating unique electronic properties that make molybdenum disulfide valuable for advanced technological applications.

By studying molybdenum disulfide and similar single-layer materials, scientists hope to answer vital questions about optical or electronic properties at the atomic scale. 

New Frontier in Materials Science

The RODAS technique represents a significant leap forward in materials characterization. It empowers researchers to dynamically explore structure-property relationships during analysis, target specific atoms or defects for measurement as they form, efficiently collect data on various defect types, adapt to identify new atomic or defect classes in real-time, and minimize sample damage while maintaining detailed analysis.

By applying this technology to a single layer of vanadium-doped molybdenum disulfide, the research team gained a new understanding of defect formation and evolution under electron beam exposure. This approach allows for exploring and characterizing materials in dynamic states, offering a deeper knowledge of how materials behave under various stimuli.

“Materials science techniques such as advanced electron microscopy continue to expand our comprehension of the physical world, and systems such as RODAS could play a crucial role in accelerating discovery and innovation,” Roccapriore said. “The ability to observe and analyze materials at the atomic scale in real time shows potential for pushing the boundaries in computing, electronics and beyond, and ultimately enabling the development of transformative technologies.”

ORNL’s Laboratory Directed Research and Development program sponsored the work as part of its Interconnected Science Ecosystem, or INTERSECT, initiative. STEM experiments were supported by the DOE Office of Science Basic Energy Sciences, Materials Sciences and Engineering Division and performed at the Center for Nanophase Materials Sciences, a DOE Office of Science user facility at ORNL. This work was supported as part of the Center for the Science of Synthesis Across Scales, an Energy Frontier Research Center funded by the DOE Office of Science Basic Energy Sciences at the University of Washington.

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