Argonne National Laboratory researchers have made a breakthrough in qubit technology, demonstrating an ultra-low noise platform that utilizes electrons trapped on solid neon. This innovation achieves a significant reduction in noise levels, outperforming most semiconductor-based qubits by a factor of 10 to 10,000. The system boasts a coherence time of approximately 0.1 milliseconds, nearly 1,000 times longer than its semiconducting counterparts, while maintaining high gate fidelity. This indicates improved stability and accuracy in quantum operations, making it a strong candidate for scalable quantum computing. The low noise levels are attributed to neon's chemically inert and impurity-free properties1. This development has significant implications for the field of quantum computing, as it brings researchers closer to creating reliable and efficient quantum systems. So what matters to practitioners is that this breakthrough could pave the way for the development of more robust and scalable quantum computers.