Thermodynamic networks using non-equilibrium steady states achieve universal function approximation when engineered with negative differential conductance, as shown in quantum dot and enzymatic examples for sine fitting and MNIST classification.
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Quantum capacitance diagrams in a quantum-dot Kitaev chain identify the sweet spot for Majorana modes and reveal distinct parity switches from lead coupling versus quasiparticle poisoning.
Numerical simulations predict that tensile or unstrained germanium heterostructures yield spin splittings over 100 times larger than compressive cases, enabling GHz Andreev spin qubits with 100 ns all-electric gates.
citing papers explorer
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Thermodynamic Networks: Harnessing Non-Equilibrium Steady States for Computation
Thermodynamic networks using non-equilibrium steady states achieve universal function approximation when engineered with negative differential conductance, as shown in quantum dot and enzymatic examples for sine fitting and MNIST classification.
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Quantum capacitance and parity switching of a quantum-dot-based Kitaev chain
Quantum capacitance diagrams in a quantum-dot Kitaev chain identify the sweet spot for Majorana modes and reveal distinct parity switches from lead coupling versus quasiparticle poisoning.
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Strain engineering of Andreev spin qubits in Germanium
Numerical simulations predict that tensile or unstrained germanium heterostructures yield spin splittings over 100 times larger than compressive cases, enabling GHz Andreev spin qubits with 100 ns all-electric gates.