Controlling magnetic skyrmion-based interconnects for low-power spintronic memory devices
magnetic skyrmions
spintronics
memory devices
interconnects
low-power computing
Harnessing attojoule energy regimes for next-generation optoelectronic computing
attojoule electronics
photonic computing
energy-efficient computing
quantum limits
nanophotonics
Optimizing sparse mixture-of-experts models for energy-efficient AI training
sparse models
mixture-of-experts
AI efficiency
computational cost
neural networks
Optimizing exascale cooling systems via two-phase immersion for 2025 data center deployment
exascale computing
immersion cooling
thermal management
data centers
energy efficiency
Within quantum coherence windows for error-corrected photonic quantum computing
quantum coherence
photonic qubits
error correction
quantum computing
fault tolerance
Spin relaxation timescales in quantum dots for fault-tolerant computing
spin relaxation
quantum dots
fault tolerance
quantum computing
coherence time
Investigating quantum coherence windows for error-resistant photonic quantum computing architectures
quantum coherence
photonic computing
quantum error correction
qubits
quantum optics
At spin relaxation timescales for quantum memory optimization
quantum computing
spin dynamics
coherence time
qubit storage
magnetic resonance
Ultra-low-power spin-based computing using magnetic skyrmion-based interconnects
spintronics
chiral magnets
nanomagnetic logic
topological protection
Using 2D material heterostructures for ultra-low-power quantum computing architectures
2D materials
heterostructures
quantum computing
qubits
nanoelectronics
Through few-shot hypernetworks to rapidly adapt quantum error correction codes for noisy hardware
few-shot hypernetworks
quantum error correction
noisy quantum hardware
meta-learning
adaptive algorithms
Probing spin relaxation timescales in quantum dots for next-generation spintronic devices
spin relaxation
quantum dots
spintronics
coherence time
quantum computing