German Aerospace Center (DLR) and Cambridge Quantum Partner

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.

 

Cambridge Quantum and Total Announce Multi-Year Collaboration

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.

 

Cambridge Quantum Pioneers Quantum Machine Learning Methods for Reasoning

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.

 

Cambridge Quantum Releases TKET Version 0.8

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.

 

Cambridge Quantum Announces Largest Ever Natural Language Processing Implementation on a Quantum Computer

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.

 

CrownBio and JSR Life Sciences Partner with Cambridge Quantum to Leverage Quantum Machine Learning for Novel Cancer Treatment Biomarker Discovery

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.

 

IBM Invests in Cambridge Quantum

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.

 

Cambridge Quantum Releases TKET Version 0.7 with Open Access to all Python Users

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.

 

Cambridge Quantum Posts Foundational Scientific Papers on “Meaning Aware” Quantum Natural Language Processing

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.

 

NPL and Cambridge Quantum Collaborate in Quantum Computing

German Aerospace Center (DLR) and Cambridge Quantum Partner

To Use Quantum Computers to Build Better Battery Simulation Models

Cambridge Quantum has partnered with the German Aerospace Center (Deutsches Zentrum für Luft und Raumfahrt, DLR) to explore how quantum computing could help create better simulation models for battery development to aid future energy utilisation.

The collaboration will see DLR – the national aeronautics and space research centre of the Federal Republic of Germany – use Cambridge Quantum’s quantum algorithms for solving partial differential equation (PDE) systems to render a 1D simulation of a lithium-ion battery cell.

This lays the groundwork for exploring multi-scale simulations of complete battery cells with quantum computers, which are considered a viable alternative for rendering full 3D models. A multi-scale approach incorporates information from different system levels (e.g. atomistic, molecular, and macroscopic) to make a simulation more manageable and realistic, potentially accelerating battery research and development for a variety of sustainable energy solutions.

Improving battery cells has an important role to play in mobile and portable application, such as smartphones, wearable electronic devices, and electric cars, as well as in decentralised solar storage and frequency stabilisation of the energy grid. Battery research could also eventually reduce the industry’s reliance on lithium – the aterial used in commercial batteries.

DLR has previously used classical computer modelling to research a range of different battery types, including lithium-ion and beyond-lithium technologies.

This is one of the earliest works combining partial differential equation models for battery simulation and near-term quantum computing. Using Cambridge Quantum’s software development framework for execution on NISQ (Noisy Intermediate-Scale Quantum) computers, DLR will render its quantum simulations on an IBM Q quantum computer.

 

ABOUT DLR

DLR is the Federal Republic of Germany’s research centre for aeronautics and space. It uses the expertise of its 55 research institutes and facilities to develop solutions to global challenges, climate, mobility and technology. The DLR Institute of Engineering Thermodynamics performs research in the field of efficient energy storage systems that conserve natural resources and next generation energy conversion technologies with a staff of 180 scientific and technical employees, engineers and doctoral candidates. The spectrum of activities ranges from theoretical studies to laboratory work for fundamental research and to the operation of pilot plants. At the Helmholtz Institute Ulm (HIU) the department of Computational Electrochemistry is working on theory-based material, electrode, and cell design for batteries.