Atomfair Brainwave Hub: SciBase II / Advanced Materials and Nanotechnology / Advanced materials for energy and computing

Advanced materials for energy and computing

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Within quantum coherence windows, how do topological qubits outperform traditional superconducting qubits?

quantum coherence topological qubits superconducting qubits error correction quantum computing

In quantum vacuum fluctuations near superconducting qubit architectures

quantum computing vacuum noise decoherence Josephson junctions Casimir effect

Quantum error correction strategies at the thermodynamic coherence limits of qubits

quantum computing coherence time error mitigation thermodynamics qubit design

For room-temperature superconductors in quantum computing and energy grids

superconductivity quantum computing energy efficiency material science room-temperature applications

Employing magnetic skyrmion-based interconnects for ultra-low-power computing architectures

skyrmions spintronics nanoelectronics low-power computing quantum materials

Advancing quantum computing through magnetic skyrmion-based interconnects for error correction

quantum computing skyrmions error correction spintronics interconnects

Using waste-heat thermoelectrics for passive cooling in high-performance computing systems

waste-heat recovery thermoelectrics passive cooling data centers energy efficiency

In attojoule energy regimes for ultra-low-power quantum computing

attojoule energy quantum computing low-power electronics quantum bits nanoscale physics

Designing exascale system integration frameworks for lattice cryptography-based biochemical simulations

exascale computing lattice cryptography biochemical simulations data security high-performance computing

Optimizing quantum error correction via backside power delivery networks in superconducting qubits

quantum computing error correction power delivery superconducting qubits noise reduction

Developing sparse mixture-of-experts models for energy-efficient AI inference

mixture-of-experts sparse models AI efficiency neural networks edge computing

Controlling quantum coherence at spin relaxation timescales in molecular qubits

quantum computing spin relaxation molecular qubits coherence time quantum control