Interactions govern the flow of information and the formation of correlations between
constituents of many-body quantum systems, dictating phases of matter found in nature and …

Quantum walks provide a framework for designing quantum algorithms that is both intuitive
and universal. To leverage the computational power of these walks, it is important to be able …

A frequent starting point of quantum computation platforms is the two-state quantum system,
ie, the qubit. However, in the context of integer optimization problems, relevant to scheduling …

Quantum computing technology has demonstrated the potential to outperform classical
computing systems in a variety of different areas. Worldwide, research within the past …

Cold atoms in an optical cavity have been widely used for quantum simulations of many-
body physics, where the quantum control capability has been advancing rapidly in recent …

Central spin systems, in which a central spin is singled out and interacts nonlocally with
several bath spins, are paradigmatic models for nitrogen-vacancy centers and quantum …

Quantum computing is an emerging technology that is expected to realize an exponential
increase in computing power. Recently, its theoretical foundation and application scenarios …

Controllable quantum many-body systems are platforms for fundamental investigations into
the nature of entanglement and promise to deliver computational speed-up for a broad class …

Recent advances in quantum computing systems attract tremendous attention. Commercial
companies, such as IBM, Amazon, and IonQ, have started to provide access to noisy …

Quantum information distribution in a tripartite state plays a fundamental role in quantum
information processes. Here we investigate how a bipartite unitary transformation UAB …