Researchers from the National University of Singapore (NUS) have recently achieved a significant breakthrough in the development of next-generation carbon-based quantum materials, opening new horizons for advancements in quantum electronics.
The innovation involves a novel type of graphene nanoribbon (GNR), named Janus GNR (JGNR). The material has a unique zigzag edge, with a special ferromagnetic edge state located on one of the edges. This unique design enables the realization of a one-dimensional ferromagnetic spin chain, which could have important applications in quantum electronics and quantum computing.
The research was led by Associate Professor Lu Jiong and his team from the NUS Department of Chemistry, in collaboration with international partners, and is published in Nature.
Graphene nanoribbons, which are narrow strips of nanoscale honeycomb carbon structures, exhibit remarkable magnetic properties due to the behavior of unpaired electrons in the atoms’ π-orbitals. Through atomically precise engineering of their edge structures into a zigzag arrangement, a one-dimensional spin-polarized channel can be constructed.
This feature offers immense potential for applications in spintronic devices or serving as next-generation multi-qubit systems, which are the fundamental building blocks of quantum computing.
Janus, the ancient Roman god of beginnings and endings, is often depicted as having two faces pointing in opposite directions, representing the past and the future. The term “Janus” has been applied in materials science to describe materials that have different properties on opposite sides. JGNR has a novel structure with only one edge of the ribbon having a zigzag form, making it the world’s first one-dimensional ferromagnetic carbon chain.
This design is achieved by employing a Z-shaped precursor design which introduces a periodic array of hexagon carbon rings on one of the zigzag edges, breaking the structural and spin symmetry of the ribbon.
Assoc. Prof Lu said, “Magnetic graphene nanoribbons—narrow strips of graphene formed by fused benzene rings—offer tremendous potential for quantum technologies due to their long spin coherence times and the potential to operate at room temperature. Creating a one-dimensional single zigzag edge in such systems is a daunting yet essential task for realizing the bottom-up assembly of multiple spin qubits for quantum technologies.”
The significant achievement is a result of close collaboration among synthetic chemists, materials scientists, and theoretical physicists, including Professor Steven G Louie from UC Berkeley in the United States, Professor Hiroshi Sakaguchi from Kyoto University in Japan and other contributing authors.
Creating the Janus graphene nanoribbons
To produce the JGNR, the researchers initially designed and synthesized a series of special “Z-shape” molecular precursors via conventional in-solution chemistry. These precursors were then used for subsequent on-surface synthesis, which is a new type of solid-phase chemical reaction performed in an ultra-clean environment. This approach allowed the researchers to precisely control the shape and structure of the graphene nanoribbons at the atomic level.
The Z-shape design allows for the asymmetric fabrication by independently modifying one of the two branches, thereby creating a desired “defective” edge, while maintaining the other zigzag edge unchanged. Moreover, adjusting the length of the modified branch enables the modulation of the width of the JGNRs.
Characterization via state-of-art scanning probe microscopy/spectroscopy and first-principles density functional theory confirms the successful fabrication of JGNRs with a ferromagnetic ground state exclusively localized along the single zigzag edge.
“The rational design and on-surface synthesis of a novel class of JGNR represent a conceptual and experimental breakthrough for realizing one-dimensional ferromagnetic chain. Creating such JGNRs not only expands the possibilities for precise engineering of exotic quantum magnetism and enables the assembly of robust spin arrays as new-generation qubits.
“Furthermore, it enables the fabrication of one-dimensional spin-polarized transport channels with tunable bandgaps, which could advance carbon-based spintronics at the one-dimensional limit,” added Assoc. Prof Lu.
