SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4214622182> ?p ?o ?g. }

Showing items 1 to 100 of ±147 with 100 items per page.

W4214622182 endingPage "1921" @default.
W4214622182 startingPage "1915" @default.
W4214622182 abstract "Spin-forbidden excitons in monolayer transition metal dichalcogenides are optically inactive at room temperature. Probing and manipulating these dark excitons are essential for understanding exciton spin relaxation and valley coherence of these 2D materials. Here, we show that the coupling of dark excitons to a metal nanoparticle-on-mirror cavity leads to plasmon-induced resonant emission with the intensity comparable to that of the spin-allowed bright excitons. A three-state quantum model combined with full-wave electrodynamic calculations reveals that the radiative decay rate of the dark excitons can be enhanced by nearly 6 orders of magnitude through the Purcell effect, therefore compensating its intrinsic nature of weak radiation. Our nanocavity approach provides a useful paradigm for understanding the room-temperature dynamics of dark excitons, potentially paving the road for employing dark exciton in quantum computing and nanoscale optoelectronics." @default.
W4214622182 created "2022-03-02" @default.
W4214622182 creator A5014515439 @default.
W4214622182 creator A5031978474 @default.
W4214622182 creator A5032918441 @default.
W4214622182 creator A5037303480 @default.
W4214622182 creator A5045818251 @default.
W4214622182 creator A5046846228 @default.
W4214622182 creator A5060533468 @default.
W4214622182 date "2022-02-28" @default.
W4214622182 modified "2023-10-11" @default.
W4214622182 title "Plasmonic Nanocavity Induced Coupling and Boost of Dark Excitons in Monolayer WSe<sub>2</sub> at Room Temperature" @default.
W4214622182 cites W1561553867 @default.
W4214622182 cites W1784198049 @default.
W4214622182 cites W1966513995 @default.
W4214622182 cites W1983051112 @default.
W4214622182 cites W2013384653 @default.
W4214622182 cites W2017871657 @default.
W4214622182 cites W2023147957 @default.
W4214622182 cites W2042688191 @default.
W4214622182 cites W2045079968 @default.
W4214622182 cites W2050842165 @default.
W4214622182 cites W2070740251 @default.
W4214622182 cites W2075381039 @default.
W4214622182 cites W2077204417 @default.
W4214622182 cites W2088783732 @default.
W4214622182 cites W2092044679 @default.
W4214622182 cites W2096628382 @default.
W4214622182 cites W2255825515 @default.
W4214622182 cites W2274913285 @default.
W4214622182 cites W2281996747 @default.
W4214622182 cites W2288883857 @default.
W4214622182 cites W2297801396 @default.
W4214622182 cites W2331792393 @default.
W4214622182 cites W2417818976 @default.
W4214622182 cites W2472109776 @default.
W4214622182 cites W2508330981 @default.
W4214622182 cites W2515391095 @default.
W4214622182 cites W2554274035 @default.
W4214622182 cites W2561131700 @default.
W4214622182 cites W2562280399 @default.
W4214622182 cites W2583084107 @default.
W4214622182 cites W2593424154 @default.
W4214622182 cites W2615133416 @default.
W4214622182 cites W2748351075 @default.
W4214622182 cites W2755918156 @default.
W4214622182 cites W2767185672 @default.
W4214622182 cites W2774647842 @default.
W4214622182 cites W2886531226 @default.
W4214622182 cites W2889852158 @default.
W4214622182 cites W2891919452 @default.
W4214622182 cites W2901047289 @default.
W4214622182 cites W2911692855 @default.
W4214622182 cites W2913033167 @default.
W4214622182 cites W2916581300 @default.
W4214622182 cites W2945289782 @default.
W4214622182 cites W2963296514 @default.
W4214622182 cites W2968318117 @default.
W4214622182 cites W3030802490 @default.
W4214622182 cites W3036305232 @default.
W4214622182 cites W3080377633 @default.
W4214622182 cites W3101161257 @default.
W4214622182 cites W3103624044 @default.
W4214622182 cites W3105678514 @default.
W4214622182 cites W3175221187 @default.
W4214622182 doi "https://doi.org/10.1021/acs.nanolett.1c04360" @default.
W4214622182 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/35225629" @default.
W4214622182 hasPublicationYear "2022" @default.
W4214622182 type Work @default.
W4214622182 citedByCount "17" @default.
W4214622182 countsByYear W42146221822022 @default.
W4214622182 countsByYear W42146221822023 @default.
W4214622182 crossrefType "journal-article" @default.
W4214622182 hasAuthorship W4214622182A5014515439 @default.
W4214622182 hasAuthorship W4214622182A5031978474 @default.
W4214622182 hasAuthorship W4214622182A5032918441 @default.
W4214622182 hasAuthorship W4214622182A5037303480 @default.
W4214622182 hasAuthorship W4214622182A5045818251 @default.
W4214622182 hasAuthorship W4214622182A5046846228 @default.
W4214622182 hasAuthorship W4214622182A5060533468 @default.
W4214622182 hasConcept C110879396 @default.
W4214622182 hasConcept C111154242 @default.
W4214622182 hasConcept C120665830 @default.
W4214622182 hasConcept C121332964 @default.
W4214622182 hasConcept C124657808 @default.
W4214622182 hasConcept C15744967 @default.
W4214622182 hasConcept C165330911 @default.
W4214622182 hasConcept C171250308 @default.
W4214622182 hasConcept C17729963 @default.
W4214622182 hasConcept C184779094 @default.
W4214622182 hasConcept C192562407 @default.
W4214622182 hasConcept C26873012 @default.
W4214622182 hasConcept C2776029896 @default.
W4214622182 hasConcept C2776360541 @default.
W4214622182 hasConcept C41999313 @default.
W4214622182 hasConcept C42704618 @default.
W4214622182 hasConcept C49040817 @default.
W4214622182 hasConcept C520434653 @default.