SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2022203363> ?p ?o ?g. }

Showing items 1 to 100 of ±149 with 100 items per page.

W2022203363 abstract "Bogoliubov-de Gennes theory is used to investigate the effect of the size of a superconducting square on the vortex states in the quantum confinement regime. When the superconducting coherence length is comparable to the Fermi wavelength, the shape resonances of the superconducting order parameter have strong influence on the vortex configuration. Several unconventional vortex states, including asymmetric ones, giant multi-vortex combinations, and states comprising giant antivortex, were found as ground states and their stability was found to be very sensitive on the value of $k_Fxi_0$, the size of the sample $W$, and the magnetic flux $Phi$. By increasing the temperature and/or enlarging the size of the sample, quantum confinement is suppressed and the conventional mesoscopic vortex states as predicted by the Ginzburg-Laudau (GL) theory are recovered. However, contrary to the GL results we found that the states containing symmetry-induced vortex-antivortex pairs are stable over the whole temperature range. It turns out that the inhomogeneous order parameter induced by quantum confinement favors vortex-antivortex molecules, as well as giant vortices with a rich structure in the vortex core - unattainable in the GL domain." @default.
W2022203363 created "2016-06-24" @default.
W2022203363 creator A5008739085 @default.
W2022203363 creator A5015834940 @default.
W2022203363 creator A5044606922 @default.
W2022203363 creator A5077601154 @default.
W2022203363 creator A5088041073 @default.
W2022203363 date "2013-10-07" @default.
W2022203363 modified "2023-09-30" @default.
W2022203363 title "Vortex states in nanoscale superconducting squares: The influence of quantum confinement" @default.
W2022203363 cites W1482184502 @default.
W2022203363 cites W1494096203 @default.
W2022203363 cites W1606038203 @default.
W2022203363 cites W1964988902 @default.
W2022203363 cites W1967873367 @default.
W2022203363 cites W1967984301 @default.
W2022203363 cites W1972038945 @default.
W2022203363 cites W1978678691 @default.
W2022203363 cites W1983313322 @default.
W2022203363 cites W1984222812 @default.
W2022203363 cites W1984448321 @default.
W2022203363 cites W1987170022 @default.
W2022203363 cites W1988829538 @default.
W2022203363 cites W1989429500 @default.
W2022203363 cites W1989591145 @default.
W2022203363 cites W1995323148 @default.
W2022203363 cites W1995418237 @default.
W2022203363 cites W2002277150 @default.
W2022203363 cites W2004469595 @default.
W2022203363 cites W2005888647 @default.
W2022203363 cites W2006522970 @default.
W2022203363 cites W2008425941 @default.
W2022203363 cites W2008556390 @default.
W2022203363 cites W2010379415 @default.
W2022203363 cites W2012212494 @default.
W2022203363 cites W2014111456 @default.
W2022203363 cites W2014365418 @default.
W2022203363 cites W2021287874 @default.
W2022203363 cites W2021773372 @default.
W2022203363 cites W2024622388 @default.
W2022203363 cites W2024684321 @default.
W2022203363 cites W2030926192 @default.
W2022203363 cites W2031824068 @default.
W2022203363 cites W2033704381 @default.
W2022203363 cites W2033845579 @default.
W2022203363 cites W2047165241 @default.
W2022203363 cites W2049999421 @default.
W2022203363 cites W2050622556 @default.
W2022203363 cites W2051164253 @default.
W2022203363 cites W2051563893 @default.
W2022203363 cites W2056241521 @default.
W2022203363 cites W2056336687 @default.
W2022203363 cites W2056407925 @default.
W2022203363 cites W2061230643 @default.
W2022203363 cites W2063241792 @default.
W2022203363 cites W2063397337 @default.
W2022203363 cites W2064166173 @default.
W2022203363 cites W2065283692 @default.
W2022203363 cites W2067722807 @default.
W2022203363 cites W2070940560 @default.
W2022203363 cites W2076010797 @default.
W2022203363 cites W2077491027 @default.
W2022203363 cites W2081525304 @default.
W2022203363 cites W2082202768 @default.
W2022203363 cites W2083296289 @default.
W2022203363 cites W2083535813 @default.
W2022203363 cites W2090922956 @default.
W2022203363 cites W2091242664 @default.
W2022203363 cites W2093083097 @default.
W2022203363 cites W2095046890 @default.
W2022203363 cites W2095334405 @default.
W2022203363 cites W2102767676 @default.
W2022203363 cites W2108351503 @default.
W2022203363 cites W2118197186 @default.
W2022203363 cites W2127600584 @default.
W2022203363 cites W2150322615 @default.
W2022203363 cites W2154421583 @default.
W2022203363 cites W2312308100 @default.
W2022203363 cites W2949915790 @default.
W2022203363 cites W2963581545 @default.
W2022203363 cites W3099644035 @default.
W2022203363 cites W3101449680 @default.
W2022203363 doi "https://doi.org/10.1103/physrevb.88.144501" @default.
W2022203363 hasPublicationYear "2013" @default.
W2022203363 type Work @default.
W2022203363 sameAs 2022203363 @default.
W2022203363 citedByCount "20" @default.
W2022203363 countsByYear W20222033632014 @default.
W2022203363 countsByYear W20222033632015 @default.
W2022203363 countsByYear W20222033632016 @default.
W2022203363 countsByYear W20222033632017 @default.
W2022203363 countsByYear W20222033632019 @default.
W2022203363 countsByYear W20222033632020 @default.
W2022203363 countsByYear W20222033632021 @default.
W2022203363 countsByYear W20222033632022 @default.
W2022203363 countsByYear W20222033632023 @default.
W2022203363 crossrefType "journal-article" @default.
W2022203363 hasAuthorship W2022203363A5008739085 @default.
W2022203363 hasAuthorship W2022203363A5015834940 @default.
W2022203363 hasAuthorship W2022203363A5044606922 @default.