Open positions
Open calls
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Summer positions at the Quantum technology laboratory
Application deadline: April 9, 2025
We are always on the look-out motivated postdoctoral researchers to join our cutting-edge experimental research team specializing in superconducting circuits. Exciting opportunities are available in three key areas:
✅ Quantum Thermodynamics
✅ Quantum Computing with Bosonic Modes
✅ Quantum-Enabled Technologies
If you’re interested, contact Simone Gasparinetti at simoneg@chalmers.se.
We also welcome MSc and PhD students, as well as summer students and interns eager to gain hands-on experience in quantum research.
🔹 Be part of the future of quantum technology—apply today! 🔹
Quantum thermodynamics
This research direction aims to deepen our understanding of thermodynamic principles at the quantum level. You will investigate how quantum systems exchange energy and information. This pillar offers the chance to study quantum thermal machines which are counterparts of heat engines, quantum refrigerators, and clocks.
Quantum computing with bosonic modes
Building on our group’s recent achievements in the preparation, manipulation, and tomography of quantum information encoded in highly coherent bosonic modes, this effort focuses on the advanced aspects of quantum information processing using continuous-variable systems. You will work on exploiting the high dimensionality of bosonic mode Hilbert spaces, implementing sophisticated quantum error correction protocols, and extending our platform to multiple microwave cavities. The aim is to demonstrate a verifiable quantum speed-up advantage and to explore the potential benefits of bosonic architectures, such as longer coherence times and resource-efficient quantum error correction.
Quantum-enabled technologies
This research direction involves the development of next-generation technologies essential for advancing quantum applications. It includes designing novel components such as electromagnetic filters and quantum chip shielding as well as enhancing hardware efficiency by developing microwave switches vital for scaling quantum computing.
You would play a role which would involve several of the following aspects of our experimental research:
- conceive and design novel quantum devices
- execute microwave measurements with nearly quantum-limited noise performance
- work on customized solutions to control bosonic modes
- work on multi-mode aspects of bosonic platforms
- perform material studies and develop nanofabrication processes to advance the state of the art in qubit lifetime and coherence
- fabricate superconducting devices for your own project as well as for other teams in our group
- contribute with any of your prior fabrication expertise, potentially as a lead member of our fabrication team
10 reasons to join our team
- State-of-the-art facilities for fabrication and experiments
- Cutting-edge electronics
- Deep knowledge of hardware for quantum control and measurements
- Long-lived superconducting qubits
- Diverse and inclusive work environment
- Opportunities for local, national, and international collaboration
- A research agenda covering fundamental and applied science
- The ambition to make a difference