The Austrian joint effort between the University of Innsbruck and AQT has successfully demonstrated the integration of a quantum computer (QC) into a high-performance-computing (HPC) environment. This hybrid infrastructure can now be used to tackle challenges in various fields such as chemistry, material sciences, or optimization.

Storage and manipulation of quantum information can be affected by disturbances from the environment. However due to the precision control of laser light and magnetic fields, the quantum memory on AQT’s quantum computers persists for the equivalent of up to 1000 quantum gate operations.

AQT successfully demonstrates a Quantum Volume of 128 on its 19-inch rack-compatible Quantum Computer system PINE. The Quantum Volume Test is an internationally applied benchmark that assesses and describes the computational power of a quantum computer with a single number.

Algorithm depth is key to implement quantum applications, which means that error rates should be as low as possible. We demonstrated error rates of less than 1 in 100 to help you push for novel use-cases.

Industry standards such as the 19-inch rack facilitate the integration of novel technologies into existing infrastructure. Here, AQT has demonstrated the first rack-based quantum computer supporting 20 qubits.

A capacity of 20 qubits, requiring less than 2 sqm footprint, power consumption of less than 2 kW, perfect for the installation at high-performance computing infrastructures and data-centers.

The Austrian joint effort between the University of Innsbruck and AQT has successfully demonstrated the integration of a quantum computer (QC) into a high-performance-computing (HPC) environment. This hybrid infrastructure can now be used to tackle challenges in various fields such as chemistry, material sciences, or optimization.

Our international joint effort between QC Ware (United States of America), AQT (Austria), Covestro (Germany) and Boehringer Ingelheim (Germany) has successfully implemented a quantum algorithm that is able to estimate electrostatic interaction energies of complex molecules on an AQT trapped ion quantum computer.

Quantum computer systems promise to revolutionize chemistry and material science. Especially, electronic structure calculations allow to determine material properties with high precision. On our Quantum Computer, this is exemplified by determining the potential energy landscape of a hydrogen molecule, allowing us to estimate the energy, state, and interatomic distance of the molecular ground state.

The integration of quantum computing in the manufacturing industry holds significant promise for advancing value creation by optimizing various aspects in manufacturing processes.

A capacity of 20 qubits, requiring less than 2 sqm footprint, power consumption of less than 2 kW, perfect for the installation at high-performance computing infrastructures and data-centers.

The Austrian joint effort between the University of Innsbruck and AQT has successfully demonstrated the integration of a quantum computer (QC) into a high-performance-computing (HPC) environment. This hybrid infrastructure can now be used to tackle challenges in various fields such as chemistry, material sciences, or optimization.

A capacity of 20 qubits, requiring less than 2 sqm footprint, power consumption of less than 2 kW, perfect for the installation at high-performance computing infrastructures and data-centers.