We show how to implement stationary one-way quantum steering with strong entanglement
in a cavity magnonic system that consists of two magnon modes and a microwave cavity …

We demonstrate a scheme for the generation of bipartite and tripartite entanglement, as well
as he implementation of stable and controllable long-distance one-way and asymmetric two …

We consider a three-mode optomechanical system in which two mechanical oscillators are
independently coupled to a cavity mode driven by two controllable lasers. By controlling the …

We investigate in detail the properties of the stationary quantum steering of two mechanical
modes, where the two mechanical modes interact with two coupling cavity modes, and two …

A scheme is proposed to generate long‐distance entanglement and asymmetric steering
between mechanical oscillator and magnon mode across the frequency difference of≈ 10 …

In a general two-mode cavity optomechanical system driven with a mildly amplitude
modulated light field, we investigate in detail the properties of entanglement and asymmetric …

In the cavity-magnonics system, the coupling between microwave photon and magnon is of
beam-splitter (BS) interaction, which in general does not support steady-state entanglement …

Quantum steering displays an inherent asymmetric property that differs from entanglement
and Bell nonlocality. Besides being of fundamental interest, steering is relevant to many …

We consider a hybrid atom-optomechanical system consisting of a mechanical membrane
inside an optical cavity and an atomic Bose-Einstein condensate outside the cavity. The …

Abstract Einstein–Podolsky–Rosen (EPR) steering as a form of quantum correlation lies
between entanglement and Bell nonlocality and exhibits an inherent asymmetry between …