Developing quantum devices capable of advancing chemistry research

The major challenge, really, for all of us who are using those devices today is to try to get a set of qubits to play a tune

Credit: Institute of Informatics, University of Amsterdam, The Netherlands

Qubit topology, communication overhead, and noise fundamentally shape the performance and scalability of quantum computing systems. Professor Peter Coveney’s insights from decades of multi-disciplinary computing research

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Where hype meets reality: why breakthrough computing technologies must prove their scientific worth

High-performance computing, artificial intelligence, and quantum computing are transforming scientific research, enabling breakthroughs in drug discovery, climate modelling, and materials science. But how do we ensure billion-dollar investments in advanced computing infrastructure deliver tangible scientific value?