Topological order from finite-depth unitaries, measurement and feedforward: Part II

Long-range entanglement -- the backbone of topologically ordered states -- cannot be created in finite time using local unitary circuits, or equivalently, adiabatic state preparation. Recently it has come to light that single-site measurements provide a loophole, allowing for finite-time state preparation in certain cases. I will explore how this observation imposes a complexity hierarchy on long-range entangled states based on the minimal number of measurement layers required to create the state. I will argue that certain phases of matter cannot be prepared using any finite number of layers, while remarkably certain non-Abelian topological orders can be prepared in a single round of measurement. The ingredients to implement such protocols are readily available in current NISQ devices.