This article explores how materials science is advancing quantum computing through innovative material applications. Key studies reveal that perovskites, kagome lattices, and chiral nanomaterials may improve quantum stability, control, and error correction. Researchers from Argonne National Lab have shown that adding neodymium to perovskites stabilizes light-controlled electron spins, enhancing qubit coherence. Rice University’s findings on kagome lattices challenge magnetic behavior theories, offering potential for advanced quantum logic applications. Additionally, studies on chiral nanomaterials suggest novel ways to precisely manipulate quantum spin states, supporting progress in quantum information technologies.
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