Preserving coherence long enough to perform meaningful calculations is one of the major
challenges on the pathway to large-scale quantum-computer implementations. Noise …

As the advances in quantum hardware bring us into the noisy intermediate-scale quantum
(NISQ) era, one possible task we can perform without quantum error correction using NISQ …

The silicon metal-oxide-semiconductor (MOS) material system is a technologically important
implementation of spin-based quantum information processing. However, the MOS interface …

Quantum computation relies on accurate measurements of qubits not only for reading the
output of the calculation, but also to perform error correction. Most proposed scalable silicon …

Once the periodic properties of elements were unveiled, chemical behaviour could be
understood in terms of the valence of atoms. Ideally, this rationale would extend to quantum …

Spin–orbit effects, inherent to electrons confined in quantum dots at a silicon heterointerface,
provide a means to control electron spin qubits without the added complexity of on-chip …

Quantum computing has the potential to create a paradigm shift in computing technology,
which can lead to breakthroughs in emerging applications that rely on ultra-high …

Many quantum computing platforms are based on a two-dimensional (2D) physical layout.
Here we explore a concept called looped pipelines, which permits one to obtain many of the …

A single electron spin in a double quantum dot in a magnetic field is considered in terms of a
four-level system. By describing the electron motion between the potential minima via spin …

For the realization of a quantum computer, a good qubit design as the basic building block is
a nontrivial starting point. To fully leverage the potential of quantum computing, quantum …