Atomic Physics Seminars

Measurement-based quantum computing is a promising paradigm of quantum computation, where universal computing is achieved through a sequence of local measurements. The backbone of this approach is the preparation of multipartite entanglement, known as cluster states. While a cluster state with two-dimensional (2D) connectivity is required for universality, a three-dimensional (3D) cluster state is necessary for additionally achieving fault tolerance [1,2]. However, the challenge of making 3D connectivity has limited cluster state generation up to 2D [3,4].

In this talk, I will present an experiment generation of a 3D cluster state based on the continuous-variable optical platform [5]. To realize 3D connectivity, we harness a crucial advantage of time-frequency modes of ultrafast quantum light: an arbitrary complex mode basis can be accessed directly, enabling connectivity as desired. We demonstrate the versatility of our method by generating cluster states with 1D, 2D, and 3D connectivities. For their complete characterization, we develop a quantum state tomography method for multimode Gaussian states. Moreover, we verify the cluster state generation by nullifier measurements as well as full inseparability tests. Our work paves the way toward fault-tolerant and universal measurement-based quantum computing.

As another topic, I will present a recent experiment that characterizes a multimode Gaussian process by obtaining the complete information including non-unitary evolution [6]. While the multimode processes are currently the most relevant in photonic quantum optics and quantum information science experiments, the resource-efficient characterization of such processes remains challenging. I will present experimental results of characterizing a sixteen-mode Gaussian process.