SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2014358648> ?p ?o ?g. }

Showing items 1 to 100 of ±150 with 100 items per page.

W2014358648 abstract "Dynamically corrected gates were recently introduced [K. Khodjasteh and L. Viola, Phys. Rev. Lett. 102, 080501 (2009)] as a tool to achieve decoherence-protected quantum gates based on open-loop Hamiltonian engineering. Here, we further expand the framework of dynamical quantum error correction, with emphasis on elucidating under what conditions decoherence suppression can be ensured while performing a generic target quantum gate, using only available bounded-strength control resources. Explicit constructions for physically relevant error models are detailed, including arbitrary linear decoherence and pure dephasing on qubits. The effectiveness of dynamically corrected gates in an illustrative non-Markovian spin-bath setting is investigated numerically, confirming the expected fidelity performance in a wide parameter range. Robustness against a class of systematic control errors is automatically incorporated in the perturbative error regime." @default.
W2014358648 created "2016-06-24" @default.
W2014358648 creator A5002037469 @default.
W2014358648 creator A5036492578 @default.
W2014358648 date "2009-09-14" @default.
W2014358648 modified "2023-10-12" @default.
W2014358648 title "Dynamical quantum error correction of unitary operations with bounded controls" @default.
W2014358648 cites W1879994454 @default.
W2014358648 cites W1963651172 @default.
W2014358648 cites W1964429295 @default.
W2014358648 cites W1965641466 @default.
W2014358648 cites W1969329609 @default.
W2014358648 cites W1971246484 @default.
W2014358648 cites W1978533437 @default.
W2014358648 cites W1982876678 @default.
W2014358648 cites W1983727080 @default.
W2014358648 cites W1983765908 @default.
W2014358648 cites W1999480624 @default.
W2014358648 cites W2003132673 @default.
W2014358648 cites W2011876234 @default.
W2014358648 cites W2012592597 @default.
W2014358648 cites W2014633300 @default.
W2014358648 cites W2016304634 @default.
W2014358648 cites W2022402363 @default.
W2014358648 cites W2023564955 @default.
W2014358648 cites W2027767930 @default.
W2014358648 cites W2032147770 @default.
W2014358648 cites W2034656552 @default.
W2014358648 cites W2035077743 @default.
W2014358648 cites W2045216418 @default.
W2014358648 cites W2046158380 @default.
W2014358648 cites W2049226029 @default.
W2014358648 cites W2049915174 @default.
W2014358648 cites W2052547819 @default.
W2014358648 cites W2055269795 @default.
W2014358648 cites W2055804112 @default.
W2014358648 cites W2057940730 @default.
W2014358648 cites W2073101810 @default.
W2014358648 cites W2074594473 @default.
W2014358648 cites W2076954515 @default.
W2014358648 cites W2077422780 @default.
W2014358648 cites W2078834989 @default.
W2014358648 cites W2079152399 @default.
W2014358648 cites W2086429680 @default.
W2014358648 cites W2087256203 @default.
W2014358648 cites W2090163642 @default.
W2014358648 cites W2092831095 @default.
W2014358648 cites W2103282498 @default.
W2014358648 cites W2123364531 @default.
W2014358648 cites W2125303188 @default.
W2014358648 cites W2139079991 @default.
W2014358648 cites W2147195941 @default.
W2014358648 cites W2158605123 @default.
W2014358648 cites W2159566537 @default.
W2014358648 cites W2166123315 @default.
W2014358648 cites W2501142942 @default.
W2014358648 cites W2592411083 @default.
W2014358648 cites W3099126179 @default.
W2014358648 cites W3099282091 @default.
W2014358648 cites W3100807198 @default.
W2014358648 cites W3104110856 @default.
W2014358648 cites W4211192199 @default.
W2014358648 cites W4233474106 @default.
W2014358648 doi "https://doi.org/10.1103/physreva.80.032314" @default.
W2014358648 hasPublicationYear "2009" @default.
W2014358648 type Work @default.
W2014358648 sameAs 2014358648 @default.
W2014358648 citedByCount "89" @default.
W2014358648 countsByYear W20143586482012 @default.
W2014358648 countsByYear W20143586482013 @default.
W2014358648 countsByYear W20143586482014 @default.
W2014358648 countsByYear W20143586482015 @default.
W2014358648 countsByYear W20143586482016 @default.
W2014358648 countsByYear W20143586482017 @default.
W2014358648 countsByYear W20143586482018 @default.
W2014358648 countsByYear W20143586482019 @default.
W2014358648 countsByYear W20143586482020 @default.
W2014358648 countsByYear W20143586482021 @default.
W2014358648 countsByYear W20143586482022 @default.
W2014358648 countsByYear W20143586482023 @default.
W2014358648 crossrefType "journal-article" @default.
W2014358648 hasAuthorship W2014358648A5002037469 @default.
W2014358648 hasAuthorship W2014358648A5036492578 @default.
W2014358648 hasBestOaLocation W20143586482 @default.
W2014358648 hasConcept C104317684 @default.
W2014358648 hasConcept C121332964 @default.
W2014358648 hasConcept C121864883 @default.
W2014358648 hasConcept C122527463 @default.
W2014358648 hasConcept C126255220 @default.
W2014358648 hasConcept C130787639 @default.
W2014358648 hasConcept C134306372 @default.
W2014358648 hasConcept C17744445 @default.
W2014358648 hasConcept C185592680 @default.
W2014358648 hasConcept C191608238 @default.
W2014358648 hasConcept C194975256 @default.
W2014358648 hasConcept C199539241 @default.
W2014358648 hasConcept C203087015 @default.
W2014358648 hasConcept C2778476455 @default.
W2014358648 hasConcept C33923547 @default.
W2014358648 hasConcept C34388435 @default.