SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W1999034269> ?p ?o ?g. }

Showing items 1 to 100 of ±132 with 100 items per page.

W1999034269 abstract "Implementation of quantum controlled-NOT (CNOT) gates in realistic molecular systems is studied using stimulated Raman adiabatic passage (STIRAP) techniques optimized in the time domain by genetic algorithms or coupled with optimal control theory. In the first case, with an adiabatic solution (a series of STIRAP processes) as starting point, we optimize in the time domain different parameters of the pulses to obtain a high fidelity in two realistic cases under consideration. A two-qubit CNOT gate constructed from different assignments in rovibrational states is considered in diatomic (NaCs) or polyatomic $({text{SCCl}}_{2})$ molecules. The difficulty of encoding logical states in pure rotational states with STIRAP processes is illustrated. In such circumstances, the gate can be implemented by optimal control theory and the STIRAP sequence can then be used as an interesting trial field. We discuss the relative merits of the two methods for rovibrational computing (structure of the control field, duration of the control, and efficiency of the optimization)." @default.
W1999034269 created "2016-06-24" @default.
W1999034269 creator A5024498156 @default.
W1999034269 creator A5030294205 @default.
W1999034269 creator A5045841824 @default.
W1999034269 creator A5090834324 @default.
W1999034269 creator A5091488014 @default.
W1999034269 date "2009-10-23" @default.
W1999034269 modified "2023-09-30" @default.
W1999034269 title "Rovibrational controlled-NOT gates using optimized stimulated Raman adiabatic passage techniques and optimal control theory" @default.
W1999034269 cites W1514785357 @default.
W1999034269 cites W1969172642 @default.
W1999034269 cites W1971922715 @default.
W1999034269 cites W1972980792 @default.
W1999034269 cites W1982249714 @default.
W1999034269 cites W1984460180 @default.
W1999034269 cites W1991668317 @default.
W1999034269 cites W2002828910 @default.
W1999034269 cites W2002929378 @default.
W1999034269 cites W2009624935 @default.
W1999034269 cites W2011962392 @default.
W1999034269 cites W2014798902 @default.
W1999034269 cites W2014952988 @default.
W1999034269 cites W2017765854 @default.
W1999034269 cites W2018287320 @default.
W1999034269 cites W2018928626 @default.
W1999034269 cites W2024700546 @default.
W1999034269 cites W2030114031 @default.
W1999034269 cites W2035267156 @default.
W1999034269 cites W2036771586 @default.
W1999034269 cites W2037032930 @default.
W1999034269 cites W2037958064 @default.
W1999034269 cites W2039501535 @default.
W1999034269 cites W2044433214 @default.
W1999034269 cites W2052329548 @default.
W1999034269 cites W2053571266 @default.
W1999034269 cites W2054438887 @default.
W1999034269 cites W2054827124 @default.
W1999034269 cites W2055065376 @default.
W1999034269 cites W2055385827 @default.
W1999034269 cites W2056208981 @default.
W1999034269 cites W2066329560 @default.
W1999034269 cites W2068309237 @default.
W1999034269 cites W2069694063 @default.
W1999034269 cites W2070492779 @default.
W1999034269 cites W2073731171 @default.
W1999034269 cites W2075776048 @default.
W1999034269 cites W2077168594 @default.
W1999034269 cites W2078801616 @default.
W1999034269 cites W2087787117 @default.
W1999034269 cites W2092427275 @default.
W1999034269 cites W2095150437 @default.
W1999034269 cites W2111149313 @default.
W1999034269 cites W2123148422 @default.
W1999034269 cites W2125993136 @default.
W1999034269 doi "https://doi.org/10.1103/physreva.80.042325" @default.
W1999034269 hasPublicationYear "2009" @default.
W1999034269 type Work @default.
W1999034269 sameAs 1999034269 @default.
W1999034269 citedByCount "27" @default.
W1999034269 countsByYear W19990342692012 @default.
W1999034269 countsByYear W19990342692013 @default.
W1999034269 countsByYear W19990342692014 @default.
W1999034269 countsByYear W19990342692015 @default.
W1999034269 countsByYear W19990342692016 @default.
W1999034269 countsByYear W19990342692017 @default.
W1999034269 countsByYear W19990342692020 @default.
W1999034269 countsByYear W19990342692021 @default.
W1999034269 countsByYear W19990342692022 @default.
W1999034269 crossrefType "journal-article" @default.
W1999034269 hasAuthorship W1999034269A5024498156 @default.
W1999034269 hasAuthorship W1999034269A5030294205 @default.
W1999034269 hasAuthorship W1999034269A5045841824 @default.
W1999034269 hasAuthorship W1999034269A5090834324 @default.
W1999034269 hasAuthorship W1999034269A5091488014 @default.
W1999034269 hasConcept C109663097 @default.
W1999034269 hasConcept C111806078 @default.
W1999034269 hasConcept C121332964 @default.
W1999034269 hasConcept C126255220 @default.
W1999034269 hasConcept C167812310 @default.
W1999034269 hasConcept C182953411 @default.
W1999034269 hasConcept C184779094 @default.
W1999034269 hasConcept C202444582 @default.
W1999034269 hasConcept C2778179073 @default.
W1999034269 hasConcept C32909587 @default.
W1999034269 hasConcept C33923547 @default.
W1999034269 hasConcept C58053490 @default.
W1999034269 hasConcept C58849907 @default.
W1999034269 hasConcept C62520636 @default.
W1999034269 hasConcept C78594624 @default.
W1999034269 hasConcept C84114770 @default.
W1999034269 hasConcept C91575142 @default.
W1999034269 hasConcept C9652623 @default.
W1999034269 hasConceptScore W1999034269C109663097 @default.
W1999034269 hasConceptScore W1999034269C111806078 @default.
W1999034269 hasConceptScore W1999034269C121332964 @default.
W1999034269 hasConceptScore W1999034269C126255220 @default.
W1999034269 hasConceptScore W1999034269C167812310 @default.
W1999034269 hasConceptScore W1999034269C182953411 @default.
W1999034269 hasConceptScore W1999034269C184779094 @default.