Researchers have engineered a groundbreaking artificial quantum material, demonstrating a novel quantum state known as a higher-order topological quantum magnet.
This new state could offer unprecedented protection against decoherence, enhancing quantum technologies with its robust topological excitations that maintain higher quantum coherence than their individual components.
Quantum State Formation
When different quantum states combine, new collective states of matter can emerge. In the quantum realm, combining components such as atoms that possess quantum effects can give rise to macroscopic quantum states of matter, featuring exotic quantum excitations that do not exist anywhere else.
In a collaboration between Aalto University and the Institute of Physics CAS, researchers built an artificial quantum material, atom by atom, from magnetic titanium on top of a magnesium oxide substrate. They then carefully engineered how atoms interacted inside the material with the goal of birthing a new state of quantum matter. Jose Lado, assistant professor at Aalto University, created the theoretical design to engineer the material featuring topological quantum magnetism, and a group led by associate professor Kai Yang at the Institute of Physics CAS built and measured the artificial material using atomic manipulation with scanning tunneling microscopy.
Discovery of a New Quantum State
As a result, the researchers demonstrated for the first time a new quantum state of matter known as a higher-order topological quantum magnet. The topological magnet could represent a new way to achieve substantial protection against decoherence in quantum technology.
The research was published on August 29 in the journal Nature Nanotechnology.
Potential Applications in Quantum Technology
Beyond being interesting from the point of view of fundamental science, topological quantum many-body matter such as this new quantum magnet could have a groundbreaking impact on future quantum technologies.
“Creating a many-body topological quantum magnet makes it possible to explore an exciting new direction in physics. Excitations in topological quantum magnets have wildly different properties than those found in conventional magnets and could allow us to create new physical phenomena that are beyond the capabilities of current quantum materials,” Lado says.
Quantum Magnetism and Material Manipulation
Quantum magnets are materials that realize a quantum superposition of magnetic states, bringing quantum phenomena from the microscopic to the macroscopic scale. These materials feature exotic quantum excitations–including fractional excitations where electrons behave as if they were split into many parts–that do not exist anywhere outside of this material.
To manipulate how the atoms behaved inside the quantum material the researchers had assembled, they poked each individual atom with a tiny needle. This technique allows for the accurate probing of qubits at the atomic level. The needle, in reality an atomically sharp metal tip, served to excite the atoms’ local magnetic moment, which resulted in topological excitations with enhanced coherence.
“Topological quantum excitations, such as those realized in the topological quantum magnet we now built, can feature substantial protection against decoherence. Ultimately, the protection offered by these exotic excitations can help us overcome some of the most pressing challenges of currently available qubits,” Lado says.
Experimental Observations and Future Implications
In their experiment, the researchers observed that the topological excitations were resistant to perturbations, a feature that was also predicted in Lado’s theoretical design. The results also showed that the quantum coherence of the topological excitations was higher than their original individual components. This finding could point to a way of turning the researchers’ artificial quantum material into a building block for quantum information that is protected from decoherence.
Reference: “Construction of topological quantum magnets from atomic spins on surfaces” by Hao Wang, Peng Fan, Jing Chen, Lili Jiang, Hong-Jun Gao, Jose L. Lado and Kai Yang, 29 August 2024, Nature Nanotechnology.
DOI: 10.1038/s41565-024-01775-2
Never miss a breakthrough: Join the SciTechDaily newsletter.
Follow us on Google and Google News.
2 Comments
When different quantum states combine, new collective states of matter can emerge. In the quantum realm, combining components such as atoms that possess quantum effects can give rise to macroscopic quantum states of matter, featuring exotic quantum excitations that do not exist anywhere else.
VERY GOOD!
Please ask researchers to think deeply:
1. Is the so-called quantum high-dimensional spacetime matter or low-risk spacetime matter?
2. What is the physical reality of quantum states?
Scientific research guided by correct theories can help humanity avoid detours, failures, and pomposity. Please witness the exemplary collaboration between theoretical physicists and experimentalists (https://scitechdaily.com/microscope-spacecrafts-most-precise-test-of-key-component-of-the-theory-of-general-relativity/#comment-854286). Some people in contemporary physics has always lived in a self righteous children’s story world. Whose values have been overturned by such a comical and ridiculous reality?
Low dimensional spacetime matter is the substructure of high-dimensional spacetime matter. Topological vortices and their antivortices have identical spatiotemporal structures. The synchronous effect of countless topological vortex fractal structures makes spatiotemporal motion more complex. Symmetry is mainly manifested between topological vortices and their antivortices, rather than between the high-dimensional spacetime matter formed by their interactions. In theory, it is difficult for two molecules, two atoms, or even two so-called quanta that any observable high-dimensional spacetime objects to be absolutely identical or symmetrical.
Mathematics is the main environment for modeling problems in other areas. Observations and experiments, theory, and modeling reinforce each other and together lead to our understanding of physical phenomena. To deny the scientificity of low dimensional spacetime matter is essentially to deny the value of mathematics and its geometric shapes to science.
Is the so-called quantum high-dimensional spacetime matter or low-dimensional spacetime matter? This may be something that researchers should consider when thinking about problems.