At 202Q-Lab, we work closely with leading academic institutions, industry innovators, and research programs to advance the frontiers of quantum science.
This national research program, coordinated by Chalmers, aims to position Swedish research and industry at the forefront of quantum technology development. Its main goal is to build an advanced quantum computer capable of solving problems beyond the reach of the best existing supercomputers.
Funding: Knut and Alice Wallenberg Foundation
Josephson Gated Transistors and Electronics
2023-2027
This project aims to advance energy-efficient, densely integrated electronics for sustainable high-performance computing. The project focuses on minimizing contact resistance between metallic leads and semiconducting channels, a critical factor in improving transistor performance in next-generation circuits.
Funding: European Commission
Efficient Verification of Quantum computing architectures with Bosons (VeriQuB)
2023-2027
This project aims to develop scalable and rigorous methods for verifying bosonic quantum devices, which offer a hardware-efficient path to fault-tolerant quantum computing. By combining continuous-variable measurements with new theoretical tools, it will enable the verification of quantum speedup and support the advancement of large-scale bosonic architectures.
Funding: European Commission
HERD Infrared block filter
2023-2024
This project aims to develop an advanced infrared block filter to improve precision in superconducting quantum experiments. By enhancing infrared filtering, it supports better quantum coherence and measurement fidelity, contributing to the performance of next-generation quantum devices.
Funding: Knut and Alice Wallenberg Foundation
Experimental Search for Quantum Advantages in Thermodynamics (ESQuAT)
2023-2027
This project aims to experimentally explore quantum advantages in thermodynamics using a circuit quantum electrodynamics platform. By developing novel quantum refrigerators and an engineered physical bath, it seeks to identify nonclassical thermodynamic behaviors and demonstrate clear advantages of quantum thermal machines over classical ones.
Funding: European Commission
ASPECTS Quantum Thermodynamics of Precision in Electronic Devices
2022-2025
This project explores quantum thermodynamic limits on measurement precision in superconducting qubits and nanoelectromechanical devices. It aims to demonstrate that quantum processes can achieve higher precision with lower energy cost, advancing energy-efficient quantum technologies.
Funding: European Commission
SuPErConducTing Radio-frequency switch for qUantuM technologies (Spectrum)
2022-2025
This project develops a superconducting radio-frequency switch to control multiple qubits through a single cable, improving scalability and thermal stability in quantum processors. The technology promises ultra-fast, energy-efficient qubit control, advancing the practical deployment of quantum computers.
Funding: European Commission
Undersökning av kvantfördelar i termodynamik med supraledande kretsar
2022-2025
This project experimentally investigates quantum advantages in thermodynamics using superconducting circuits and microwave heat baths. By building quantum refrigerators that exploit quantum coherence and collective effects, it aims to reveal nonclassical thermodynamic behaviors and demonstrate the benefits of quantum thermal machines.
Funding: The Swedish Research Council (VR)
Gate Tuneable Superconducting Quantum Electronics (SuperGate)
2021-2024
This project explores the integration of gate-controlled superconducting devices into quantum electronics, aiming to combine the energy efficiency of superconductors with the scalability of semiconductors. By developing devices that can be electrically tuned via gate voltages, it seeks to enable more compact and energy-efficient quantum circuits.
Funding: European Commission