Advancements in quantum computing and materials

Forbidden physics concepts in quantum materials for unconventional superconductivity

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In quantum vacuum fluctuations to probe dark energy interactions at microscopic scales

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Enhancing quantum computing efficiency using 2D material heterostructures at cryogenic temperatures

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Within attosecond timeframes: tracking electron correlations in high-temperature superconductors

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Optimizing quantum error correction for exascale system integration by 2026

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Josephson junction frequency standards for lights-out production in semiconductor fabs

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Optimizing protein folding intermediates via quantum annealing methods for faster drug discovery

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Quantum noise suppression at Josephson junction frequencies for scalable qubit arrays

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Anticipating 2035 energy grid demands with quantum-optimized load forecasting

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Bridging quantum biology with information theory to decode cellular decision-making processes

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Designing fault-tolerant quantum algorithms by fusing Byzantine mathematics with quantum error correction

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Probing exotic quantum states at millikelvin thermal states using superconducting qubits

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