TECH
Perfect atomic layers paves the way for the next generation of quantum chips
For decades, progress in electronics has been linked to the miniaturization of components. Increasingly smaller transistors have enabled faster, more efficient, and cheaper chips. However, this strategy is reaching a delicate physical limit. When devices reach the atomic scale, almost invisible imperfections begin to seriously compromise performance. In technologies such as quantum computing, these defects can be simply fatal.
It is in this context that the recent advance by a group of researchers from South Korea gains relevance. For the first time, it was possible to manufacture atomic layers of a semiconductor continuously, virtually without flaws, and in a size compatible with industrial production.
The center of the discovery is molybdenum disulfide, known as MoS₂. It is a two-dimensional material, with a thickness equivalent to a single atom — more than a hundred times thinner than a human hair.
For years, MoS₂ has sparked interest because, unlike graphene, it is a "complete" semiconductor: it allows for controlled switching of electrical current on and off, something essential for transistors. The problem has always been manufacturing. Producing large areas of this material, uniform and without structural defects, seemed unfeasible outside the laboratory.
Microscopic defects, giant impacts...On an atomic scale, small flaws make a huge difference. In MoS₂, defects usually arise at the boundaries between crystalline domains. Although invisible to the naked eye, these imperfections interrupt the movement of electrons and destroy fundamental quantum properties.
For quantum chips, this means noise, loss of coherence, and processing errors. Eliminating these defects required something beyond point adjustments: it was necessary to control the positioning of atoms during the growth of the material.
The solution came from improving the so-called van der Waals epitaxy, applied to a special type of slightly inclined sapphire, known as a vicinal substrate. At the atomic level, this surface exhibits natural “steps” that act as invisible guides.
These steps orient the MoS₂ atoms during growth, forcing a more ordered organization. With precise control of temperature, pressure, and deposition, the researchers were able to form continuous, uniform, and virtually perfect monolayers in areas the size of a silicon wafer.
When the material proves its worth...Definitive validation came from electronic tests. The produced layers exhibited coherent quantum transport, with signs of phenomena such as weak localization and early indications of the quantum Hall effect. This indicates that electrons can move without losing their quantum phase—something essential for stable quantum chips.
In addition, the material exhibited high electron mobility. To demonstrate practical viability, the researchers fabricated complete arrays of transistors, which functioned efficiently at room temperature, close to the material's theoretical limits.
Why this matters for the future...Quantum computing requires extremely stable materials, and every defect is a potential source of error. A two-dimensional semiconductor, free of imperfections and capable of being manufactured on a large scale, removes one of the biggest bottlenecks in the sector.
More than a one-off breakthrough, the method can be adapted to other two-dimensional materials, expanding its impact on sensors, advanced memories, and low-power electronics. It doesn't mean perfect quantum chips tomorrow, but it shows that precise atomic manufacturing is already an industrial reality—and no longer just a scientific promise.
Key Atomic Layer Technologies:
Perfect Semiconductors: Researchers are producing continuous layers of semiconductors with the thickness of a single atom, with minimal defects, increasing the stability of qubits.
Artificial Atoms (Quantum Dots): Use electrons in silicon chips to create "atoms" that act as qubits, improving reliability compared to single-electron qubits.
Superconducting Qubits: Circuits made of materials such as aluminum, niobium, or tantalum, deposited on substrates (silicon/sapphire), which become superconductors at cryogenic temperatures, forming qubits in resonators.
Majorana Qubits: Nanowires formed by indium arsenide and aluminum that, at very low temperatures, generate quasiparticles (Majoranas) that store quantum information.
Ion Traps: Silicon chips with electrodes and waveguides (optical wiring) that use lasers to trap and manipulate individual ions, forming stable and scalable qubits.
Challenges and Requirements:
Stability: Qubits are extremely sensitive to vibrations, electromagnetic noise, and heating, requiring isolation and extreme cooling (near absolute zero).
Control: Precise manipulation of quantum states with lasers or microwaves for quantum operations.
Scalability: Industrial fabrication of perfect layers and large-scale control are crucial for practical quantum computers.
These approaches, combining the microfabrication of classical chips with new materials and precise atomic manipulation, are the basis for the next generation of quantum computing.
mundophone
