DIAQ: Diamond material for room temperature quantum computer
Objective We are developing diamond qubit systems for quantum computers that can operate at room temperature. To do this, we produce artificial, high-purity diamonds free from sources of interference under controlled conditions. In these, we place individual atoms…
15. February 2023
SQuAp: Spin Qubit Analysis platform for hardware based on colour centres
Objective We are developing a qualification system to analyse the functionality and properties of solid-state spin qubits. Quantum computers can be built using a variety of physical systems, including flaws in the crystal lattice of solids, where a…
8. February 2023
Legato: Prototype multichip quantum computer with up to 100 trapped-ion qubits
Objective We are developing a fully scalable trapped-ion quantum computer that interconnects four quantum computing modules. One path leading to the realisation of quantum computers with millions of qubits is to develop a basic module that can perform…
27. January 2023
QSea II: Modular and scalable ion trap quantum computer
Objective We are building a modular and scalable quantum computer based on stored ion qubits. This quantum computer is a modular and scalable advancement of the QSea I demonstrator. It is based on several modular MAGIC quantum processors…
27. January 2023
QSea I: Remote access 10-qubit ion trap-based quantum computer demonstrator
Objective We are building a 10-qubit quantum computer demonstrator based on ion trap technology with control software for remote access and, in a second step, automating operation and ensuring availability for applications at DLR. This demonstrator for an…
11. January 2023
SuNQC: Quantum computer based on NV centres in diamond with sulphur doping
We are building a quantum computer based on nitrogen-vacancy (NV) centres in diamond created by ion implementation and developing a scaling technology for far more than 50 qubits. Objective We are developing NV technology for the construction of…
5. January 2023
REDAC: Reconfigurable Discrete Analog Computer
Objective We are building a classic computer based on the paradigms of quantum-inspired classical computing and want to use analogy formation to demonstrate the superiority of analogue computing. Our objective includes the creation of a software ecosystem for…
5. January 2023
Xaphiro: Prototype trapped-ion quantum computer with at least 50 qubits
Objective We are developing a microfabricated quantum computer prototype based on ion trapping technology with at least 50 fully functional qubits. As part of the project Xaphiro we will develop and operate a powerful quantum computer based on…
5. January 2023
Toccata: Trapped-ion quantum computer with at least 50 qubits and error correction
Objective Wir bauen einen nutzungsfreundlichen, zuverlässigen und skalierbaren Quantenprozessor mit mindestens 50 Qubits auf Ionenfallentechnologie. As part of the DLR Quantum Computing Initiative, we are building a trapped-ion quantum computer with an electronic quantum computer module based on…
22. December 2022
QuiX Quantum: Photonic quantum computer with up to 64 qubits
Objective We are developing a universal and error corrected photonic quantum computer with up to 64 qubits Over the course of its four-year project, QuiX Quantum is developing a photonic quantum computer for universal quantum computing in several…