Publications by authors named "D P DiVincenzo"
The [Formula: see text] tensor, which determines the reaction of Kramers-degenerate states to an applied magnetic field, is of increasing importance in the current design of spin qubits. It is affected by details of heterostructure composition, disorder, and electric fields, but it inherits much of its structure from the effect of the spin-orbit interaction working at the crystal-lattice level. Here, we uncover interesting symmetry and topological features of [Formula: see text] for important valence and conduction bands in silicon, germanium, and gallium arsenide.
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- Large-scale superconducting quantum processors face challenges due to the complex microscopic features in solid-state devices, primarily using aluminium oxide (AlO) tunnel Josephson junctions for nonlinearity in quantum operations.
- Traditional analyses often rely on an ideal sinusoidal current-phase relation, which only applies in very low-transparency conditions, but new findings reveal this doesn’t accurately represent the energy spectra of transmon artificial atoms.
- A mesoscopic model shows significant contributions from higher Josephson harmonics, improving predictions of energy spectra and suggesting that engineered harmonics could minimize charge-related errors in transmon qubits, enhancing their performance for quantum technologies.
We develop a photonic description of short, one-dimensional electromagnetic pulses, specifically in the language of electrical transmission lines. Current practice in quantum technology, using arbitrary waveform generators, can readily produce very short, few-cycle pulses in a very-low-noise, low-temperature setting. We argue that these systems attain the limit of producing pure coherent quantum states, in which the vacuum has been displaced for a short time, and therefore over a short spatial extent.
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- The transmon qubit architecture in quantum computing behaves like systems of interconnected nonlinear quantum resonators, which require a certain degree of frequency detuning to maintain qubit state stability.
- The study explores the stability of a many-body localized phase using parameters from quantum processors from IBM, Delft, and Google, focusing on both natural and engineered disorder.
- Utilizing methods like Kullback-Leibler analysis, inverse participation ratios, and Walsh transforms, the research indicates that some quantum computing platforms may be on the verge of experiencing uncontrollable chaotic fluctuations.
We investigate the self-correcting properties of a network of Majorana wires, in the form of a trijunction, in contact with a parity-preserving thermal environment. As opposed to the case where Majorana bound states are immobile, braiding Majorana bound states within a trijunction introduces dangerous error processes that we identify. Such errors prevent the lifetime of the memory from increasing with the size of the system.
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