Charge Order competes with superconductivity
Stripe order of charge carriers in Bi2Sr2CaCu2O8+x [2]. The figure shows the structure with a period of approximately one nanometer (front) and the related diffraction pattern (back) obtained by a so-called Fourier transformation (Yazdani Lab, Princeton University).
Today in Science Express: Charge carriers in cuprate high-Tc superconductors form nanostripes that suppress superconductivity, as shown by guest researchers from Princeton and Vancouver using synchrotron radiation at BESSY II
Superconductors are materials that can conduct electricity without any loss of energy. In order to exhibit this property, however, classical superconductors need to be cooled almost to absolute zero (minus 273 degrees centigrade). Even the so-called high-Tc superconductors still require very low temperatures of minus 200 degrees centigrade. While cooling down to these temperatures involves substantial effort, superconductors are already employed in many areas, e.g., for magnetic resonance tomography in medical applications. Despite extensive research, materials providing lossless conduction of electricity at room temperature are missing up to now.
High-Tc superconductors were discovered in 1986, the Nobel prize for the discovery came only one year later. The phenomenon of superconductivity at high temperatures is found in a class of materials called the cuprates, complex compounds of copper and oxygen, and additional ingredients. They are in the focus of research for almost 30 years now. Many aspects of the high-Tc cuprates, however, are still to be understood. This is due to the subtle details determining the properties of the charge carriers in these materials. Thus, a number of competing mechanisms preclude the superconducting state.
One of the competing states of the materials is a regular stripe pattern of charge carriers on the nanoscale. This kind of order freezes the charge carriers and prevents superconductivity. Already last year, guest researchers at BESSY II could elucidate the importance of this mechanism and its connection with superconductivity in a representative group of cuprates [1]. Lead by two research groups from Princeton and Vancouver, international teams of scientists have now identified the so-called charge order as a generic property of this class of materials.
For their research, they used the XUV diffractometer developed at HZB, which is operated at the UE46_PGM1 beamline at BESSY II. Employing soft x-ray synchrotron radiation, they succeeded in detecting the elusive phenomenon of charge order and measured the related nanostructures with high precision. This is an important step towards understanding the charge order and its connection to superconductivity in the cuprates. The research was conducted in close cooperation with scientists from the Department Quantum Phenomena in Novel Materials (previously from the Institute of Complex Magnetic Materials) at HZB. The results are now published in two articles in Science [2,3]. “Identifying and understanding the mechanisms competing with superconductivity raise the hope to control and eventually deactivate them. This may be one step towards superconductivity at room temperature”, explains Dr. Eugen Weschke, who supervised the experiment at BESSY II.
[1] G. Ghiringelli et al., Long-Range Incommensurate Charge Fluctuations in (Y,Nd)Ba2Cu3O6+x, Science 337, 821 (2012).
[2] Eduardo H. da Silva Neto et al., Ubiquitous Interplay between Charge Ordering and High-Temperature Superconductivity in Cuprates, Science 2013. DOI: 10.1126/science.1243479
[3] R. Comin et al., Charge order driven by Fermi-arc instability in Bi2Sr2−xLaxCuO6+δ, Science (2013). DOI: 10.1126/science.1242996
- Key technology for a future without fossil fuelsIn June and July 2025, catalyst researcher Nico Fischer spent some time at HZB. It was his sabbatical, he was relieved of his duties as Director of the Catalysis Institute in Cape Town for several months and was able to focus on research only. His institute is collaborating with HZB on two projects that aim to develop environmentally friendly alternatives using innovative catalyst technologies. The questions were asked by Antonia Rötger, HZB.
- Scrolls from Buddhist shrine virtually unrolled at BESSY IIThe Mongolian collection of the Ethnological Museum of the National Museums in Berlin contains a unique Gungervaa shrine. Among the objects found inside were three tiny scrolls, wrapped in silk. Using 3D X-ray tomography, a team at HZB was able to create a digital copy of one of the scrolls. With a mathematical method the scroll could be virtually unrolled to reveal the scripture on the strip. This method is also used in battery research.
- Helmholtz Doctoral Award for Hanna TrzesniowskiDuring her doctoral studies at the Helmholtz Centre Berlin, Hanna Trzesniowski conducted research on nickel-based electrocatalysts for water splitting. Her work contributes to a deeper understanding of alkaline water electrolysis and paves the way for the development of more efficient and stable catalysts. On 8 July 2025, she received the Helmholtz Doctoral Prize, which honours the best and most original doctoral theses in the Helmholtz Association.