| Ferdinand Helmer, Matteo Mariantoni, Austin G. Fowler, Jan von Delft, Enrique Solano & Florian Marquardt,
Multi-mode superconducting circuits offer a promising platform for engineering robust systems for quantum computation. Previous studies have shown that single-mode devices cannot simultaneously
Reaching high speed, high fidelity qubit operations requires precise control over the shape of the underlying pulses. For weakly anharmonic systems, such as superconducting transmon qubits, short
Connections between crystal chemistry and critical temperature Tc have been in the focus of superconductivity, one of the most widely studied phenomena in physics, chemistry, and materials science
We optimize Matrix-Product State (MPS)-based algorithms for simulating quantum circuits with finite fidelity, specifically the Time-Evolving Block Decimation (TEBD) and the Density-Matrix
| M Ganzhorn and D J Egger and P Barkoutsos and P Ollitrault and G Salis and N Moll and M Roth and A Fuhrer and P Mueller and S Woerner and I Tavernelli and S Filipp
Building quantum processor with novel properties based on superconducting qubits - this is the aim of the four year project GeQCoS ('German Quantum Computer based on Superconducting Qubits') funded
For content see "Modulhandbuch": http://www.ph.tum.de/mh?mid=PH1321
For topics see: https://www.moodle.tum.de/course/view.php?id=74956
Dear participants,
the preliminary discussion and the
The EU project OpenSuperQPlus gets underway
01 March 2023
OpenSuperQPlus unites 28 European research partners from 10 countries aiming to develop a 1,000 qubit quantum computer
The project
In diesem Buch teilen führende Vertreter aus Industrie und Forschung ihre Erfahrungen und Empfehlungen zur wirtschaftlichen Nutzbarmachung der Quantentechnologien. Verständlich geschrieben erklären
The European consortium OpenSuperQPlus (OSQ+) is making significant strides toward building Europe’s first 100-qubit quantum computer by 2026.
Mittlerweile können Forschende Quantensysteme gezielt erzeugen und ihren Zustand präzise kontrollieren und auslesen. Das nährt nicht nur die Hoffnung auf eine neue Generation von Computern, sondern
| Peter Mueller and Andreas Fuhrer and Stefan Filipp
"Quantum” may not be the first word that comes to mind when thinking about chemistry. But at the atomic level, the physical and chemical properties of molecules can be affected by quantum mechanical
WMI reviews the potential of its quantum computing technology for near-term simulations of quantum chemistry.
Daniel Jost was member of the Gross group at WMI as a Master and Ph.D. Student as well as postdoctoral researcher between 2015 and 2020.
Master Thesis: Spin Fluctuations and Superconductivity in
Jan Goetz was member of the Gross group as a Master and Ph.D. Student WMI between 2011 and 2017.
Master Thesis: Gradiometric Flux Quantum Bits with Tunable Tunnel Coupling (November 2011)
Just like its predecessor OpenSuperQ, the OpenSuperQPlus project is part of the European Quantum Technology Flagship. It is continuing and enhancing OpenSuperQ and brings together most of its team
Haftungsausschluss
Die Bayerische Akademie der Wissenschaften hat alle in ihrem Bereich bereitgestellten Informationen nach bestem Wissen und Gewissen erarbeitet und geprüft. Es wird jedoch keine
Career
The Walther-Meissner-Institute has a long tradition in training and fostering young talents. To this end we are aiming at attracting the best students and young scientists from all over the
| M. Ganzhorn, G. Salis, D. J. Egger, A. Fuhrer, M. Mergenthaler, C. Müller, P. Müller, S. Paredes, M. Pechal, M. Werninghaus, and S. Filipp
Quantum Computing with Superconducting Qubits: Basic Concepts (0000001346) W 2025
Exercise to Quantum Computing with Superconducting Qubits: Basic Concepts (0000001350) W 2025
Exercise to Quantum Computing with Superconducting Qubits: Basic Concepts (0000001350) W 2025
One of the main limitations in state-of-the art solid-state quantum processors is qubit decoherence and relaxation due to noise from adsorbates on surfaces, impurities at interfaces, and material
Mission statement
The Walther-Meißner-Institute for Low Temperature Research (WMI) is a research institute of the Bavarian Academy of Sciences and Humanities (BAdW). It conducts fundamental and
With the availability of additional laboratory space and the success of the WMI in Germany's Excellence Initiative (2006-2018), Excellence Strategy (starting from 2019), and other third-party
Superconducting Quantum Computing: Multi-qubit operations Quantum Optimal Control Quantum Neural Networks
Speculative Application for PhD/PostDoc positions [Initiativbewerbung]
We are continuously looking for excellent and motivated PhD students and postdoctoral researchers to join our research
This project explores the potential of multi-qubit gates for quantum computing on a superconducting qubit platform. The main goal is to develop superconducting architectures and control methods to
The goal of this research project is to explore the potential of multi-qubit gates for quantum computing. The main focus is on speeding up quantum algorithms based on the variational quantum
Dr. Stefan Filipp holds a position as Full Professor (Chair) in Physics at the TU Munich and as Director of the Walther-Meißner-Institute of the Bavarian Academy of Sciences and Humanities since May
After focusing on Quantum Information and Technology while studying physics at the Technical University of Munich, Niklas Bruckmoser joined the Quantum Computing group as a Master’s Student in
Matteo Mariantoni was Member of the Gross group at WMI as a Ph.D. student between 2003 and 2009.
Ph.D. Thesis: New Trends in Superconducting Circuit Quantum Electrodynamics: Two Amplifiers, Two
BMBF-funded activity on realizing a German Quantum Processor lead by the WMI has started.
Join us for a workshop on quantum computing games!
Discover what moves the world! This was the motto of the Münchener Wissenschaftstage 2021, taking place at the Deutsches Museum Verkehrszentrum from October 08 to 10. WMI supported the scientific
Quantum Computing with Superconducting Qubits: architecture and algorithms (0000000961) S 2016
Exercise to Quantum Computing with Superconducting Qubits: architecture and algorithms (0000000962) W 2015
Quantum Computing with Superconducting Qubits 2: Advanced Topics (0000001847) W 2025
Exercise to Quantum Computing with Superconducting Qubits 2: Advanced Topics (0000001848) W 2025
