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Establishing robust isolated spins on solid surfaces is crucial for fabricating quantum bits or qubits, sensors, and single-atom catalysts. An isolated spin is a single spin that is shielded from external interactions. Because isolated spins can maintain their state for long periods, they are ideal for use as qubits, the basic units of quantum computation, and for ultrafast spintronic memory.

Consequently, significant research has been dedicated to identifying materials capable of producing a stable isolated quantum spin. Candidates include single atoms of transition metals such as copper (Cu) in the Cu-phthalocyanine molecule (CuPc), molecular magnets, nitrogen-vacancy centers in diamonds, and two-dimensional layered materials.

One way to detect an isolated spin is by observing a zero-bias peak (ZBP) in the electrical conductance of, for example, a noble metal substrate containing a CuPc molecule. The ZBP results from the interaction between conduction electrons on the substrate and the isolated spin.

So far, the engineering of these ZBPs has been mainly limited to noble metal surfaces, such as gold and silver. These surfaces are rich in conduction electrons, which, while useful for ZBP, can also scatter a spin and flip its state, causing it to disturb the intrinsic spin state. This makes them unsuitable for use as qubits. As a solution, researchers have turned to insulating films, which lack conduction electrons and can host more stable spins.

In a breakthrough, a research team led by Associate Professor Toyo Kazu Yamada from the Graduate School of Engineering at Chiba University, Japan, demonstrated isolated spins on an insulating solid surface laid over a magnetic substrate.

"In this study, we successfully realized isolated spins on an insulating magnesium oxide (MgO) surface placed on a ferromagnetic iron substrate–Fe(001)," explains Dr. Yamada. "Since insulating surfaces do not have conduction electrons, quantum spins can remain more stable. Moreover, the MgO/Fe(001) structure that we used is already widely used in spintronics, making our approach highly accessible."

The team also included Mr. Kyoei Ishi, Dr. Nana Nazriq, and Dr. Peter Krüger, also from Chiba University. Their study was in the journal Nanoscale Horizons on July 30, 2025.

The researchers, in the study, focused on placing a CuPc molecule on a MgO/Fe(001) interface. The first hurdle they faced was to grow an atomically flat MgO layer on an Fe(001) substrate. They found that developing an oxygen coating on Fe(001) can provide an atomically flat surface.

This enabled them to epitaxially grow a flat MgO film on the oxygen-coated Fe(001) substrate using chemical vapor deposition in an ultra-high vacuum. Finally, after trial and error, they successfully adsorbed a CuPc molecule onto the insulating MgO surface.

"A unique feature of our design is the use of a ferromagnetic iron substrate," says Dr. Yamada. "While a magnetic surface would normally interact with and change the state of an isolated spin, the insulating layer between the substrate and the CuPc molecule prevents direct interaction, keeping the spin stable."

To confirm the presence of isolated spins, they conducted scanning tunneling spectroscopy of the fabricated sample and looked for a ZBP. Since MgO lacks conduction electrons, they did not initially expect a ZBP to appear. However, upon close examination, they clearly observed a clear ZBP that emerged via indirect coupling of the isolated spin and conduction electrons in the Fe(001) substrate through the MgO surface.

This suggests that insulating films can support the formation of isolated spins, even on ferromagnetic substances. Interestingly, the ZBP also appeared on the MgO surface outside the CuPc, which is not found in noble metal surfaces.

"Our study marks a remarkable achievement for research on isolated spins," remarks Dr. Yamada. "Because the MgO/Fe(001) surface is already widely used in tunnel magnetoresistance devices, our findings suggest it may be possible to integrate qubits using existing thin-film fabrication methods."

This study opens a new direction for isolated spin research, posing magnetic substrates, already widely used in spintronic devices, as a new platform for holding and manipulating qubits, paving the way for more accessible quantum computing.