New 2D Superconductor Forms at Higher Temperatures Than Ever Before
April 28, 2021 | Jared Sagoff, ANLEstimated reading time: 4 minutes
New interfacial superconductor has novel properties that raise new fundamental questions and might be useful for quantum information processing or quantum sensing.
Interfaces in solids form the basis for much of modern technology. For example, transistors found in all our electronic devices work by controlling the electrons at interfaces of semiconductors. More broadly, the interface between any two materials can have unique properties that are dramatically different from those found within either material separately, setting the stage for new discoveries.
Like semiconductors, superconducting materials have many important implications for technology, from magnets for MRIs to speeding up electrical connections or perhaps making possible quantum technology. The vast majority of superconducting materials and devices are 3D, giving them properties that are well understood by scientists.
One of the foundational questions with superconducting materials involves the transition temperature — the extremely cold temperature at which a material becomes superconducting. All superconducting materials at regular pressures become superconducting at temperatures far below the coldest day outside.
Now, researchers at the U.S. Department of Energy’s Argonne National Laboratory have discovered a new way to generate 2D superconductivity at a material interface at a relatively high — though still cold — transition temperature. This interfacial superconductor has novel properties that raise new fundamental questions and might be useful for quantum information processing or quantum sensing.
In the study, Argonne postdoctoral researcher Changjiang Liu and colleagues, working in a team led by Argonne materials scientist Anand Bhattacharya, have discovered that a novel 2D superconductor forms at the interface of an oxide insulator called KTaO3 (KTO). Their results were published online in the journal Science on February 12.
In 2004, scientists observed a thin sheet of conducting electrons between two other oxide insulators, LaAlO3 (LAO) and SrTiO3 (STO). It was later shown that that this material, called a 2D electron gas (2DEG) can even become superconducting — allowing the transport of electricity without dissipating energy. Importantly, the superconductivity could be switched on and off using electric fields, just like in a transistor.
However, to achieve such a superconducting state, the sample had to be cooled down to about 0.2 K — a temperature that is close to absolute zero (– 273.15 °C), requiring a specialized apparatus known as a dilution refrigerator. Even with such low transition temperatures (TC), the LAO/STO interface has been heavily studied in the context of superconductivity, spintronics and magnetism.
In the new research, the team discovered that in KTO, interfacial superconductivity could emerge at much higher temperatures. To obtain the superconducting interface, Liu, graduate student Xi Yan and coworkers grew thin layers of either europium oxide (EuO) or LAO on KTO using state-of-the-art thin film growth facilities at Argonne.
“This new oxide interface makes the application of 2D superconducting devices more feasible,” Liu said. ?“With its order-of-magnitude higher transition temperature of 2.2 K, this material will not need a dilution refrigerator to be superconducting. Its unique properties raise many interesting questions.”
A Strange Superconductor
Surprisingly, this new interfacial superconductivity shows a strong dependence on the orientation of the facet of the crystal where the electron gas is formed.
Adding to the mystery, measurements suggest the formation of stripe-like superconductivity in lower doping samples where rivulets of superconducting regions are separated by normal, nonsuperconducting regions. This kind of spontaneous stripe formation is also called nematicity, and is usually found in liquid crystal materials used for displays.
“Electronic realizations of nematicity are rare and of great fundamental interest. It turns out that EuO overlayer is magnetic, and the role of this magnetism in realizing the nematic state in KTO remains an open question,” Bhattacharya said.
In their Science paper, the authors also discuss the reasons why the electron gas forms. Using atomic resolution transmission electron microscopes, Jianguo Wen at the Center for Nanoscale Materials at Argonne, along with Professor Jian-Min Zuo’s group at the University of Illinois at Urbana-Champaign, showed that defects formed during the growth of the overlayer may play a central role.
In particular, they found evidence for oxygen vacancies and substitutional defects, where the potassium atoms are replaced by europium or lanthanum ions — all of which add electrons to the interface and turn it into a 2D conductor. Using ultrabright X-rays at the Advanced Photon Source (APS), Yan along with Argonne scientists Hua Zhou and Dillon Fong, probed the interfaces of KTO buried under the overlayer and observed spectroscopic signatures of these extra electrons near the interface.
“Interface-sensitive X-ray toolkits available at the APS empower us to reveal the structural basis for the 2DEG formation and the unusual crystal-facet dependence of the 2D superconductivity. A more detailed understanding is in progress,” Zhou said.
Beyond describing the mechanism of 2DEG formation, these results point the way to improving the quality of the interfacial electron gas by controlling synthesis conditions. Being that the superconductivity occurs for both the EuO and LAO oxide overlayers that have been tried thus far, many other possibilities remain to be explored.
Testimonial
"Advertising in PCB007 Magazine has been a great way to showcase our bare board testers to the right audience. The I-Connect007 team makes the process smooth and professional. We’re proud to be featured in such a trusted publication."
Klaus Koziol - atgSuggested Items
Curing and Verification in PCB Shadow Areas
09/17/2025 | Doug Katze, DymaxDesign engineers know a simple truth that often complicates electronics manufacturing: Light doesn’t go around corners. In densely populated PCBs, adhesives and coatings often fail to fully cure in shadowed regions created by tall ICs, connectors, relays, and tight housings.
Marcy’s Musings: Advancing the Advanced Materials Discussion
09/17/2025 | Marcy LaRont -- Column: Marcy's MusingsAs the industry’s most trusted global source of original content about the electronics supply chain, we continually ask you about your concerns, what you care about, and what you most want to learn about. Your responses are insightful and valuable. Thank you for caring enough to provide useful feedback and engage in dialogue.
September 2025 PCB007 Magazine: The Future of Advanced Materials
09/16/2025 | I-Connect007 Editorial TeamMoore’s Law is no more, and the advanced material solutions being developed to grapple with this reality are surprising, stunning, and perhaps a bit daunting. Buckle up for a dive into advanced materials and a glimpse into the next chapters of electronics manufacturing.
I-Connect007 Launches Advanced Electronics Packaging Digest
09/15/2025 | I-Connect007I-Connect007 is pleased to announce the launch of Advanced Electronics Packaging Digest (AEPD), a new monthly digital newsletter dedicated to one of the most critical and rapidly evolving areas of electronics manufacturing: advanced packaging at the interconnect level.
Panasonic Industry will Double the Production Capacity of MEGTRON Multi-layer Circuit Board Materials Over the Next Five Years
09/15/2025 | Panasonic Industry Co., Ltd.Panasonic Industry Co., Ltd., a Panasonic Group company, announced plans for a major expansion of its global production capacity for MEGTRON multi-layer circuit board materials today. The company plans to double its production over the next five years to meet growing demand in the AI server and ICT infrastructure markets.