Cupric Oxide Exhibiting Both Magnetic and Dielectric Properties at Room Temperature
—Experimental Confirmation of Room-Temperature Multiferroic Behavior Using Neutron Diffraction under High Pressure—
2022.11.17
National Institute for Materials Science (NIMS)
NIMS, the Rutherford Appleton Laboratory in the UK and the University of Oxford in the UK have experimentally confirmed that a cupric oxide exhibits multiferroic state at room temperature under high pressure.
(”Room-temperature type-II multiferroic phase induced by pressure in cupric oxide” Noriki Terada, Dmitry D. Khalyavin, Pascal Manuel, Fabio Orlandi, Christopher J. Ridley, Craig L. Bull, Ryota Ono, Igor Solovyev, Takashi Naka, Dharmalingam Prabhakaran, and Andrew T. Boothroyd; Journal: Physical Review Letters [November 16, 2022(JST)]; DOI : 10.1103/PhysRevLett.129.217601)
Abstract
- The National Institute for Materials Science (NIMS), the Rutherford Appleton Laboratory in the UK and the University of Oxford in the UK have experimentally confirmed that a cupric oxide exhibits multiferroic state (i.e., both magnetic and ferroelectric properties) at room temperature under high pressure. The theoretical model constructed in this research is expected to facilitate the development of next-generation memory devices and optical modulators.
- Multiferroic materials are potentially applicable to the development of next-generation memory devices and energy-efficient optical modulators. However, because most of these materials are functional only at temperatures below 100 K, scientists had worked for years to make them exhibit multiferroic properties at room temperature—a requirement for devices that need to operate at ambient temperatures. This research team focused on cupric oxide—a multiferroic material—because when it is subjected to high pressure, the copper and oxide ions constituting it change their positions relative to each other, significantly increasing the magnetic interactions between them. Due to this phenomenon, it had been theoretically suggested to be able to exhibit multiferroic properties at room temperature. However, this had not been experimentally confirmed due to the inability to directly measure atomic spin (i.e., atomic-level magnetism) under high pressure.
- The research team developed a high-pressure generator which also enables the measurement of atomic spin under high pressure. Using this apparatus, the team confirmed through neutron diffraction experiments that cupric oxide is able to exhibit multiferroic state at room temperature under high pressure. In addition, NIMS developed a new calculation method and used it to build a theoretical model which is expected to facilitate the development of room-temperature multiferroic materials. This calculation method was designed to operate effectively without requiring a large number of predetermined assumptions related to the strength of the magnetic interactions taking place between specific copper ions under high pressure.
- The cupric oxide compound is able to exhibit its room-temperature multiferroic state only when subjected to a high pressure of 18.5 GPa (185,000 atm). Thin films composed of precisely distorted crystals grown in accordance with the theoretical model may potentially be able to exhibit such properties at ambient atmospheric pressure.
- This research was carried out by an international research team consisting of Noriki Terada (Principal Researcher, Research Center for Advanced Measurement and Characterization, NIMS), Igor Solovyev (Principal Researcher, International Center for Materials Nanoarchitectonics, NIMS), Takashi Naka (Chief Researcher, Research Center for Functional Materials, NIMS) and researchers from the Rutherford Appleton Laboratory and the University of Oxford. This work was supported by the JSPS Grants-in-Aid for Joint International Research (grant number: 17KK0099) and the JST Support Program (project number: JPMJMI18A3).
- This research was published in the online version of Physical Review Letters, a journal of the American Physical Society, on November 15, 2022, local time (November 16, Japan Time).
Related files
- Research Center for Advanced Measurement and Characterization
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Noriki Terada
Principal Researcher
Neutron Scattering Group
Light/Quantum Beam Field
Research Center for Advanced Measurement and Characterization
National Institute for Materials Science
Tel: +81-29-860-4627
E-Mail: TERADA.Noriki=nims.go.jp
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National Institute for Materials Science
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