38 research outputs found
Near-ultrastrong nonlinear light-matter coupling in superconducting circuits
The interaction between an atom and an electromagnetic mode of a resonator is
of both fundamental interest and is ubiquitous in quantum technologies. Most
prior work studies a linear light-matter coupling of the form , where measured
relative to photonic () and atomic () mode frequencies can
reach the ultrastrong regime (). In contrast, a
nonlinear light-matter coupling of the form has the advantage of commuting with the atomic
and photonic Hamiltonian,
allowing for fundamental operations such as quantum-non-demolition measurement.
However, due to the perturbative nature of nonlinear coupling, the
state-of-the-art is limited to
. Here, we use a superconducting circuit architecture featuring a
quarton coupler to experimentally demonstrate, for the first time, a
near-ultrastrong nonlinear coupling of a superconducting
artificial atom and a nearly-linear resonator. We also show signatures of
light-light nonlinear coupling
(), and
MHz matter-matter nonlinear coupling
() which represents
the largest reported interaction between two coherent qubits. Such
advances in the nonlinear coupling strength of light, matter modes enable new
physical regimes and could lead to applications such as orders of magnitude
faster qubit readout and gates
Universal non-adiabatic control of small-gap superconducting qubits
Resonant transverse driving of a two-level system as viewed in the rotating
frame couples two degenerate states at the Rabi frequency, an amazing
equivalence that emerges in quantum mechanics. While spectacularly successful
at controlling natural and artificial quantum systems, certain limitations may
arise (e.g., the achievable gate speed) due to non-idealities like the
counter-rotating term. Here, we explore a complementary approach to quantum
control based on non-resonant, non-adiabatic driving of a longitudinal
parameter in the presence of a fixed transverse coupling. We introduce a
superconducting composite qubit (CQB), formed from two capacitively coupled
transmon qubits, which features a small avoided crossing -- smaller than the
environmental temperature -- between two energy levels. We control this
low-frequency CQB using solely baseband pulses, non-adiabatic transitions, and
coherent Landau-Zener interference to achieve fast, high-fidelity, single-qubit
operations with Clifford fidelities exceeding . We also perform coupled
qubit operations between two low-frequency CQBs. This work demonstrates that
universal non-adiabatic control of low-frequency qubits is feasible using
solely baseband pulses
Generating spatially entangled itinerant photons with waveguide quantum electrodynamics
Realizing a fully connected network of quantum processors requires the ability to distribute quantum entanglement. For distant processing nodes, this can be achieved by generating, routing, and capturing spatially entangled itinerant photons. In this work, we demonstrate the deterministic generation of such photons using superconducting transmon qubits that are directly coupled to a waveguide. In particular, we generate two-photon N00N states and show that the state and spatial entanglement of the emitted photons are tunable via the qubit frequencies. Using quadrature amplitude detection, we reconstruct the moments and correlations of the photonic modes and demonstrate state preparation fidelities of 84%. Our results provide a path toward realizing quantum communication and teleportation protocols using itinerant photons generated by quantum interference within a waveguide quantum electrodynamics architecture
Microwave Package Design for Superconducting Quantum Processors
Solid-state qubits with transition frequencies in the microwave regime, such
as superconducting qubits, are at the forefront of quantum information
processing. However, high-fidelity, simultaneous control of superconducting
qubits at even a moderate scale remains a challenge, partly due to the
complexities of packaging these devices. Here, we present an approach to
microwave package design focusing on material choices, signal line engineering,
and spurious mode suppression. We describe design guidelines validated using
simulations and measurements used to develop a 24-port microwave package.
Analyzing the qubit environment reveals no spurious modes up to 11GHz. The
material and geometric design choices enable the package to support qubits with
lifetimes exceeding 350 {\mu}s. The microwave package design guidelines
presented here address many issues relevant for near-term quantum processors.Comment: 15 pages, 9 figure