FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3036937150> ?p ?o ?g. }

• W3036937150 abstract "A challenge in building large-scale superconducting quantum processors is to find the right balance between coherence, qubit addressability, qubit-qubit coupling strength, circuit complexity and the number of required control lines. Leading all-microwave approaches for coupling two qubits require comparatively few control lines and benefit from high coherence but suffer from frequency crowding and limited addressability in multi-qubit settings. Here, we overcome these limitations by realizing an all-microwave controlled-phase gate between two transversely coupled transmon qubits which are far detuned compared to the qubit anharmonicity. The gate is activated by applying a single, strong microwave tone to one of the qubits, inducing a coupling between the two-qubit $|f,grangle$ and $|g,erangle$ states, with $|grangle$, $|erangle$, and $|frangle$ denoting the lowest energy states of a transmon qubit. Interleaved randomized benchmarking yields a gate fidelity of $97.5pm 0.3 %$ at a gate duration of $126,rm{ns}$, with the dominant error source being decoherence. We model the gate in presence of the strong drive field using Floquet theory and find good agreement with our data. Our gate constitutes a promising alternative to present two-qubit gates and could have hardware scaling advantages in large-scale quantum processors as it neither requires additional drive lines nor tunable couplers." @default.
• W3036937150 created "2020-06-25" @default.
• W3036937150 creator A5004928029 @default.
• W3036937150 creator A5009221825 @default.
• W3036937150 creator A5016075205 @default.
• W3036937150 creator A5028768642 @default.
• W3036937150 creator A5047448178 @default.
• W3036937150 creator A5053246172 @default.
• W3036937150 creator A5058972047 @default.
• W3036937150 creator A5066676848 @default.
• W3036937150 creator A5066703927 @default.
• W3036937150 date "2020-10-21" @default.
• W3036937150 modified "2023-10-12" @default.
• W3036937150 title "Demonstration of an All-Microwave Controlled-Phase Gate between Far-Detuned Qubits" @default.
• W3036937150 cites W1483238455 @default.
• W3036937150 cites W1530691225 @default.
• W3036937150 cites W1602939995 @default.
• W3036937150 cites W1622166638 @default.
• W3036937150 cites W1735687393 @default.
• W3036937150 cites W1803064406 @default.
• W3036937150 cites W1830943758 @default.
• W3036937150 cites W1963734567 @default.
• W3036937150 cites W1966456031 @default.
• W3036937150 cites W1968850365 @default.
• W3036937150 cites W1975860547 @default.
• W3036937150 cites W1983727080 @default.
• W3036937150 cites W1991022685 @default.
• W3036937150 cites W1992629111 @default.
• W3036937150 cites W1998243191 @default.
• W3036937150 cites W2007344469 @default.
• W3036937150 cites W2016321815 @default.
• W3036937150 cites W2017293193 @default.
• W3036937150 cites W2027127692 @default.
• W3036937150 cites W2035576925 @default.
• W3036937150 cites W2041497060 @default.
• W3036937150 cites W2041677824 @default.
• W3036937150 cites W2051587874 @default.
• W3036937150 cites W2053683946 @default.
• W3036937150 cites W2060904747 @default.
• W3036937150 cites W2062506119 @default.
• W3036937150 cites W2073776126 @default.
• W3036937150 cites W2078904144 @default.
• W3036937150 cites W2079099822 @default.
• W3036937150 cites W2084222475 @default.
• W3036937150 cites W2091654902 @default.
• W3036937150 cites W2173810284 @default.
• W3036937150 cites W2211717363 @default.
• W3036937150 cites W2298410160 @default.
• W3036937150 cites W2349001675 @default.
• W3036937150 cites W2560309622 @default.
• W3036937150 cites W2692657948 @default.
• W3036937150 cites W2784953480 @default.
• W3036937150 cites W2867265463 @default.
• W3036937150 cites W2889557380 @default.
• W3036937150 cites W2903516100 @default.
• W3036937150 cites W2921384226 @default.
• W3036937150 cites W2955112879 @default.
• W3036937150 cites W2963069249 @default.
• W3036937150 cites W2963698419 @default.
• W3036937150 cites W2996018287 @default.
• W3036937150 cites W3002718752 @default.
• W3036937150 cites W3033912009 @default.
• W3036937150 cites W3100351229 @default.
• W3036937150 cites W3101240002 @default.
• W3036937150 cites W3101479050 @default.
• W3036937150 cites W3101947274 @default.
• W3036937150 cites W3102174613 @default.
• W3036937150 cites W3102464785 @default.
• W3036937150 cites W3102758745 @default.
• W3036937150 cites W3103558166 @default.
• W3036937150 cites W3105570830 @default.
• W3036937150 cites W3106358725 @default.
• W3036937150 cites W3106422982 @default.
• W3036937150 doi "https://doi.org/10.1103/physrevapplied.14.044039" @default.
• W3036937150 hasPublicationYear "2020" @default.
• W3036937150 type Work @default.
• W3036937150 sameAs 3036937150 @default.
• W3036937150 citedByCount "25" @default.
• W3036937150 countsByYear W30369371502020 @default.
• W3036937150 countsByYear W30369371502021 @default.
• W3036937150 countsByYear W30369371502022 @default.
• W3036937150 countsByYear W30369371502023 @default.
• W3036937150 crossrefType "journal-article" @default.
• W3036937150 hasAuthorship W3036937150A5004928029 @default.
• W3036937150 hasAuthorship W3036937150A5009221825 @default.
• W3036937150 hasAuthorship W3036937150A5016075205 @default.
• W3036937150 hasAuthorship W3036937150A5028768642 @default.
• W3036937150 hasAuthorship W3036937150A5047448178 @default.
• W3036937150 hasAuthorship W3036937150A5053246172 @default.
• W3036937150 hasAuthorship W3036937150A5058972047 @default.
• W3036937150 hasAuthorship W3036937150A5066676848 @default.
• W3036937150 hasAuthorship W3036937150A5066703927 @default.
• W3036937150 hasBestOaLocation W30369371502 @default.
• W3036937150 hasConcept C119599485 @default.
• W3036937150 hasConcept C121332964 @default.
• W3036937150 hasConcept C122527463 @default.
• W3036937150 hasConcept C127413603 @default.
• W3036937150 hasConcept C131584629 @default.
• W3036937150 hasConcept C184720557 @default.
• W3036937150 hasConcept C191897082 @default.

• next