Harvard Unveils Innovative Approach to High-Temperature Superconductors

Fabrication method could facilitate materials discovery.

• Harvard team led by Philip Kim innovates in high-temperature superconductors using cuprates.
• Developed the world’s first superconducting diode, advancing quantum computingPerforming computation using quantum-mechanical phenomena such as superposition and entanglement.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]” tabindex=”0″ role=”link”>quantum computing.
• Demonstrated directional supercurrent and control over quantum states in BSCCO.

Superconductors have intrigued physicists for decades. But these materials, which allow the perfect, lossless flow of electrons, usually only exhibit this quantum-mechanical peculiarity at temperatures so low – a few degrees above absolute zeroAbsolute zero is the theoretical lowest temperature on the thermodynamic temperature scale. At this temperature, all atoms of an object are at rest and the object does not emit or absorb energy. The internationally agreed-upon value for this temperature is −273.15 °C (−459.67 °F; 0.00 K).” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]” tabindex=”0″ role=”link”>absolute zero – as to render them impractical.

A research team led by Harvard Professor of Physics and Applied Physics Philip Kim has demonstrated a new strategy for making and manipulating a widely studied class of higher-temperature superconductors, called cuprates, clearing a path to engineering new, unusual forms of superconductivity in previously unattainable materials.

Using a uniquely low-temperature device fabrication method, Kim and his team report in the journal Science a promising candidate for the world’s first high-temperature, superconducting diode – essentially, a switch that makes current flow in one direction – made out of thin cuprate crystals. Such a device could theoretically fuel fledging industries like quantum computing, which rely on fleeting mechanical phenomena that are difficult to sustain.

Graphical representation of the stacked, twisted cuprate superconductor, with accompanying data in the background. Credit: Lucy Yip, Yoshi Saito, Alex Cui, Frank Zhao

“High-temperature superconducting diodes are, in fact, possible, without application of magnetic fields, and open new doors of inquiry toward exotic materials study,” Kim said.

Cuprates are copper oxides that, decades ago, upended the physics world by showing they become superconducting at much higher temperatures than theorists had thought possible, “higher” being a relative term (the current record for a cuprate superconductor is -225 FahrenheitThe Fahrenheit scale is a temperature scale, named after the German physicist Daniel Gabriel Fahrenheit and based on one he proposed in 1724. In the Fahrenheit temperature scale, the freezing point of water freezes is 32 °F and water boils at 212 °F, a 180 °F separation, as defined at sea level and standard atmospheric pressure. ” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]” tabindex=”0″ role=”link”>Fahrenheit). But handling these materials without destroying their superconducting phases is extremely complex due to their intricate electronic and structural features.

The team’s experiments were led by S. Y. Frank Zhao, a former student in the Griffin Graduate School of Arts and Sciences and now a postdoctoral researcher at MITMIT is an acronym for the Massachusetts Institute of Technology. It is a prestigious private research university in Cambridge, Massachusetts that was founded in 1861. It is organized into five Schools: architecture and planning; engineering; humanities, arts, and social sciences; management; and science. MIT's impact includes many scientific breakthroughs and technological advances. Their stated goal is to make a better world through education, research, and innovation.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]” tabindex=”0″ role=”link”>MIT. Using an air-free, cryogenic crystal manipulation method in ultrapure argon, Zhao engineered a clean interface between two extremely thin layers of the cuprate bismuth strontium calcium copper oxide, nicknamed BSCCO (“bisco”). BSCCO is considered a “high-temperature” superconductor because it starts superconducting at about -288 Fahrenheit – very cold by practical standards, but astonishingly high among superconductors, which typically must be cooled to about -400.

Zhao first split the BSCCO into two layers, each one-thousandth the width of a human hair. Then, at -130, he stacked the two layers at a 45-degree twist, like an ice cream sandwich with askew wafers, retaining superconductivity at the fragile interface.

The team discovered that the maximum supercurrent that can pass without resistance through the interface is different depending on the current’s direction. Crucially, the team also demonstrated electronic control over the interfacial quantum state by reversing this polarity. This control was what effectively allowed them to make a switchable, high-temperature superconducting diode – a demonstration of foundational physics that could one day be incorporated into a piece of computing technology, such as a quantum bit.

“This is a starting point in investigating topological phases, featuring quantum states protected from imperfections,” Zhao said.

Reference: “Time-reversal symmetry breaking superconductivity between twisted cuprate superconductors” by S. Y. Frank Zhao, Xiaomeng Cui, Pavel A. Volkov, Hyobin Yoo, Sangmin Lee, Jules A. Gardener, Austin J. Akey, Rebecca Engelke, Yuval Ronen, Ruidan Zhong, Genda Gu, Stephan Plugge, Tarun Tummuru, Miyoung Kim, Marcel Franz, Jedediah H. Pixley, Nicola Poccia and Philip Kim, 7 December 2023, Science.
DOI: 10.1126/science.abl8371

The Harvard team worked with colleagues Marcel Franz at University of British Columbia and Jed Pixley at Rutgers University, whose teams previously performed theoretical calculations that accurately predicted the behavior of the cuprate superconductor in a wide range of twist angles. Reconciling the experimental observations also required new theory developments, performed by University of Connecticut’s Pavel A. Volkov.

The research was supported, in part, by the National Science Foundation, the Department of Defense, and the Department of Energy.