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UTA physicists use beams of antimatter to investigate the characteristics of advanced materials

Monday, November 9, 2015

Media Contact: Louisa Kellie, Office: 817‑272‑0864, Cell: 817-524-8926, louisa.kellie@uta.edu

News Topics: energy, physics, research

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Researchers at The University of Texas at Arlington are developing a next generation positron beam facility that will enable them to analyze the properties of advanced materials for future electronics applications such as ultra compact high-speed computers and ultra small high-powered batteries.

Initial research is focusing on the characteristics of graphene, a versatile pure carbon material 200 times stronger than steel that is expected to provide ecologically-friendly, sustainable solutions across a huge variety of applications including electronics and biotechnology. 

Positron Beam“Graphene is touted to be widely used in future applications like flexible electronics, organic LED and high-frequency transistors, “ said Dr. Alex Weiss, a UTA Distinguished Professor of Physics, department chair and principal investigator of the project. “However, the exceptional properties of this material will only get translated into real-life applications when there is a proper understanding of the microscopic interaction of graphene at stable interfaces with other materials. Our research is supporting this area.” A $640,608 National Science Foundation Major Research Instrumentation Development Grant funded the project to build the enhanced beam and develop the UTA team’s initial projects.  UTA Physics professor Ali Koymen is co-principal investigator on the grant, which continues through 2016. In their preliminary experiments, the UTA scientists used the new positron beam to explore the buried interface of eight layers of graphene on a copper substrate.  By implanting positively charged positrons on the graphene and graphene-copper interfaces, they could generate “annihilation” events with negatively charged electrons. These matter-antimatter “annihilations” produce electrons and gamma waves that carry information concerning the chemical nature, electronic structure and defects of the surfaces and interfaces at those sites.  The UTA researchers also combined two advanced positron spectroscopic techniques, a first in the world in their field, to improve the quality of their measurements. The first technique is called Positron Annihilation Induced Auger Electron Spectroscopy, or PAES, which was invented by Dr. Weiss at UTA. This tool is considered unique among surface science techniques in being able to probe both chemical content and local electronic structure of the topmost atomic layer with an extremely high level of selectivity. The other was a well-established tool for studying defects in materials, known as coincidence Doppler broadening gamma spectroscopy. “By combining their expertise and research experience, Dr. Weiss and his collaborators are building a materials characterization facility at UTA that is truly unique,” said Duane Dimos, UTA vice president of research. “It will undoubtedly result in noteworthy advances in multiple areas.” The UTA group plans to further develop the facility in the next few years by adding the capability to make measurements of the magnetic properties of nanomaterials through the addition of spin polarization – a uniform alignment of the positrons’ spin or magnetic positioning – as another unique feature to the UTA beam. That feature will allow researchers to probe magnetic structures by determining their surface electrons’ “spin state,” Dr. Koymen said. “Positrons are hundreds of times more likely to annihilate with an electron that is in the opposite spin state as opposed to a parallel spin state,” he said. “The intensity of the upgraded beam will allow us to make this kind of difficult measurements in a reasonable time frame.” Additional potential areas for research aided by the upgraded positron beam include:  •	Topological insulators, an emerging field of materials that act as insulators except for their surface, which is highly conductive. Researchers are exploring how their unique properties could lead to faster semiconductor chips for electronics. •	Tribology, the investigation of friction, lubrication and wear. Specifically, the beam can be used to examine the surface of soot particles to increase understanding of the abrasive behavior of soot in diesel engines. •	Defects in material surfaces: by measuring Doppler shift in the gamma rays to identify “lattice defects” that can degrade the performance of optical and electronic devices. The new positron beam system can save time and energy in carrying out high precision experiments. Dr. Weiss leads the Physics Department’s Experimental Condensed Matter and Positron Surface Group within the College of Science, a department also known for its work in astrophysics, nanostructured materials and high-energy physics, among other disciplines. The department is home to renowned physicist David Nygren, inventor of the Time Projection Chamber and a member of the National Academy of Sciences. Professor Kaushik De was recently elected as a Fellow of the American Physical Society for his work in developing cloud computer architectures that enabled global collaboration and big data analysis on the ATLAS experiment at the Large Hadron Collider at Switzerland-based CERN. Professor Andrew White was named APS Fellow in 2011 for his leadership role in experimental particle physics.    About The University of Texas at Arlington The University of Texas at Arlington is a comprehensive research institution of more than 51,000 students in campus-based and online degree programs and is the second-largest institution in The University of Texas System. The Chronicle of Higher Education ranked UT Arlington as one of the 20 fastest-growing public research universities in the nation in 2014. U.S. News & World Report ranks UT Arlington fifth in the nation for undergraduate diversity. The University is a Hispanic-Serving Institution and is ranked as a “Best for Vets” college by Military Times magazine. Visit www.uta.edu to learn more, and find UT Arlington rankings and recognition at http://www.uta.edu/uta/about/rankings.php.

Dr. Alex Weiss, UTA physics professor, on right, with the positron beam

“Graphene is touted to be widely used in future applications like flexible electronics, organic LED and high-frequency transistors, “ said Dr. Alex Weiss, a UTA Distinguished Professor of Physics, department chair and principal investigator of the project. “However, the exceptional properties of this material will only get translated into real-life applications when there is a proper understanding of the microscopic interaction of graphene at stable interfaces with other materials. Our research is supporting this area.”

A $640,608 National Science Foundation Major Research Instrumentation Development Grant funded the project to build the enhanced beam and develop the UTA team’s initial projects. UTA Physics professor Ali Koymen is co-principal investigator on the grant, which continues through 2016.

In their preliminary experiments, the UTA scientists used the new positron beam to explore the buried interface of eight layers of graphene on a copper substrate.

By implanting positively charged positrons on the graphene and graphene-copper interfaces, they could generate “annihilation” events with negatively charged electrons. These matter-antimatter “annihilations” produce electrons and gamma waves that carry information concerning the chemical nature, electronic structure and defects of the surfaces and interfaces at those sites.

The UTA researchers also combined two advanced positron spectroscopic techniques, a first in the world in their field, to improve the quality of their measurements.

The first technique is called Positron Annihilation Induced Auger Electron Spectroscopy, or PAES, which was invented by Dr. Weiss at UTA. This tool is considered unique among surface science techniques in being able to probe both chemical content and local electronic structure with an extremely high level of selectivity. The other was a well-established tool for studying defects in materials, known as coincidence Doppler broadening gamma spectroscopy.

“By combining their expertise and research experience, Dr. Weiss and his collaborators are building a materials characterization facility at UTA that is truly unique,” said Duane Dimos, UTA vice president of research. “It will undoubtedly result in noteworthy advances in multiple areas.”

The UTA group plans to further develop the facility in the next few years by adding the capability to make measurements of the magnetic properties of nanomaterials through the addition of spin polarization – a uniform alignment of the positrons’ spin or magnetic positioning – as another unique feature to the UTA beam.

That feature will allow researchers to probe magnetic structures by determining their surface electrons’ “spin state,” Dr. Koymen said.

“Positrons are hundreds of times more likely to annihilate with an electron that is in the opposite spin state as opposed to a parallel spin state,” he said. “The intensity of the upgraded beam will allow us to make this kind of difficult measurements in a reasonable time frame.”

Additional potential areas for research aided by the upgraded positron beam include:

  • Topological insulators, an emerging field of materials that act as insulators except for their surface, which is highly conductive. Researchers are exploring how their unique properties could lead to faster semiconductor chips for electronics.
  • Tribology, the investigation of friction, lubrication and wear. Specifically, the beam can be used to examine the surface of soot particles to increase understanding of the abrasive behavior of soot in diesel engines.
  • Defects in material surfaces: by measuring Doppler shift in the gamma rays to identify “lattice defects” that can degrade the performance of optical and electronic devices. The new positron beam system can save time and energy in carrying out high precision experiments.

Dr. Weiss is a founding member of the Positron-Surface Group within the College of Science, and, along with Dr. Koymen, is a member of the Condensed Matter Physics Group.  The UTA Physics department is also known for its work in astrophysics, nanostructured materials and high-energy physics, among other disciplines.  The group is also home to renowned physicist Dr. David Nygren, inventor of the Time Projection Chamber and a member of the National Academy of Sciences. Professor Kaushik De was recently elected as a Fellow of the American Physical Society for his work in developing cloud computer architectures that enabled global collaboration and big data analysis on the ATLAS experiment at the Large Hadron Collider at Switzerland-based CERN. Professor Andrew White was named APS Fellow in 2011 for his leadership role in experimental particle physics. Dr. Ping Liu, Dr. Ramon Lopez and Dr. David Nygren are also APS Fellows.  

About The University of Texas at Arlington

The University of Texas at Arlington is a comprehensive research institution of more than 51,000 students in campus-based and online degree programs and is the second-largest institution in The University of Texas System. The Chronicle of Higher Education ranked UT Arlington as one of the 20 fastest-growing public research universities in the nation in 2014. U.S. News & World Report ranks UT Arlington fifth in the nation for undergraduate diversity. The University is a Hispanic-Serving Institution and is ranked as a “Best for Vets” college by Military Times magazine. Visit www.uta.edu to learn more, and find UT Arlington rankings and recognition at http://www.uta.edu/uta/about/rankings.php.

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The University of Texas at Arlington is an Equal Opportunity and Affirmative Action employer.