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Lattice Resonances for Thermoplasmonics:
Lauren Zundel (4177972)
;
Kellen Malone (14304233)
;
Luis Cerdán (1789945)
..
https://figshare.com/articles/journal_contribution/Lattice_Resonances_for_Thermoplasmonics/21782624. , 2022
Link:
https://doi.org/10.1021/acsphotonics.2c01610.s001
RT Journal T1 <Title>Lattice Resonances for Thermoplasmonics</Title> UL https://suche.suub.uni-bremen.de/peid=base-ftunivfreestate:oai:figshare.com:article_21782624&Exemplar=1&LAN=DE A1 Lauren Zundel (4177972) A1 Kellen Malone (14304233) A1 Luis Cerdán (1789945) A1 Rosario Martínez-Herrero (14304236) A1 Alejandro Manjavacas (1395262) YR 2022 K1 Biophysics K1 Medicine K1 Cell Biology K1 Neuroscience K1 Physiology K1 Biotechnology K1 Evolutionary Biology K1 Ecology K1 Infectious Diseases K1 Space Science K1 Biological Sciences not elsewhere classified K1 Chemical Sciences not elsewhere classified K1 Physical Sciences not elsewhere classified K1 pulsed illumination conditions K1 energy per nanoparticle K1 coupled dipole model K1 comprehensive analysis based K1 selectively absorb light K1 nanoparticles without exciting K1 much larger increase K1 exceptional optical response K1 localized plasmons supported K1 lattice resonance absorb K1 collective mode known K1 thermoplasmonics applications exploiting K1 localized plasmons K1 lattice resonance K1 transduce light K1 metallic nanoparticles K1 exceptional properties K1 collective mode K1 lattice resonances K1 work pave K1 whose wavelength K1 tunability provided K1 thus achieve K1 thermoplasmonics thanks K1 temperature increase K1 periodic arrays K1 mostly independent K1 metallic nanostructures K1 interact coherently K1 individual nanostructures K1 ideal tools K1 giving birth K1 arrays supporting K1 analyzing arrays JF https://figshare.com/articles/journal_contribution/Lattice_Resonances_for_Thermoplasmonics/21782624 LK http://dx.doi.org/https://doi.org/10.1021/acsphotonics.2c01610.s001 DO https://doi.org/10.1021/acsphotonics.2c01610.s001 SF ELIB - SuUB Bremen
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