Superconducting qubits are one of the most promising technologies for the realization of a scalable, fault-tolerant quantum computer. Get a concise overview of how Zurich Instruments supports universities and industrial teams in achieving scalable, reliable quantum computing.
Nitrogen vacancy (NV) centers in diamond offer a prime opportunity for coherently controlling the state of a quantum system. Get a concise overview of how Zurich Instruments' qubit control and lock-in amplification expertise and solutions enable high-sensitivity measurements to be achieved quickly, in topics ranging from scanning gradiometry to heralded entanglement.
Spin-based quantum computing is a leading technology for the realization of scalable quantum computers. Get a concise overview of Zurich Instruments' key tools for spin qubit characterization, control, and readout, providing a low-noise and scalable solution that improves setup reliability and simplifies system control.
Superconducting fluxonium qubits are among the leading qubit candidates for building useful quantum computers. Since their first realization in 2009, research on fluxonium qubits has demonstrated great progress in improving qubit coherence times, control efficiency, and coupling architectures. Get a concise overview of how Zurich Instruments supports universities and industrial teams in achieving scalable, reliable quantum computing.
Superconducting bosonic qubits are a leading platform for demonstrating quantum error correction in a hardware-efficient architecture. Get a concise overview of how Zurich Instruments provides a compact and scalable solution with key features that benefit the control and measurement of bosonic qubits, from basic memory mode characterization and calibration to Wigner function tomography and two-qubit gate operations.
