Since the pioneering works by Landau, Zener, Stückelberg, and Majorana (LZSM), it has
been known that driving a quantum two-level system results in tunneling between its states …

Engineering quantum states through light–matter interaction has created a paradigm in
condensed-matter physics. A representative example is the Floquet–Bloch state, which is …

Electrons confined in Si quantum dots possess orbital, spin, and valley degrees of freedom
(DOF). We perform Landau-Zener-Stückelberg-Majorana (LZSM) interferometry on a Si …

Hybrid magnonics has recently attracted intensive attention as a promising platform for
coherent information processing. In spite of its rapid development, on-demand control over …

The ground-state criticality of many-body systems is a resource for quantum-enhanced
sensing, namely, the Heisenberg precision limit, provided that one has access to the whole …

The ability to shape photon emission facilitates strong photon-mediated interactions
between disparate physical systems, thereby enabling applications in quantum information …

Microwave driving is a ubiquitous technique for superconducting qubits, but the dressed
states description based on the conventionally used perturbation theory cannot fully capture …

The resonance and dynamics of a qubit exposed to a strong aperiodic bichromatic field are
studied by using a periodic counter‐rotating hybridized rotating wave (CHRW) Hamiltonian …

We present a unified picture of dispersive readout of quantum systems in and out of
equilibrium. A cornerstone of the approach is the backaction of the measured system to the …

We study geometric energy transport in a slowly driven single-level quantum dot weakly
coupled to electronic contacts and with strong on-site interaction, which can be either …