Optical extinction spectroscopy used to characterize metallic nanowires
We present a method for sizing metallic nanowires through the analysis of the extinction spectra of the scattered light when the wires are illuminated alternatively with p- and s-polarization waves. The method is applied to isolated silver nanowires in air or immersed in index matching oil. The diel...
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2007
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| Acceso en línea: | https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09574484_v18_n31_p_Scaffardi http://hdl.handle.net/20.500.12110/paper_09574484_v18_n31_p_Scaffardi |
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paper:paper_09574484_v18_n31_p_Scaffardi2023-06-08T15:56:36Z Optical extinction spectroscopy used to characterize metallic nanowires Lester, Marcelo Skigin, Diana Carina Electromagnetic model Index matching oil Optical extinction spectroscopy Plasmon peak position Polarization incidences Light polarization Light scattering Permittivity Spectroscopic analysis Surface plasmon resonance Transmission electron microscopy Nanowires metallic nanowire nanowire silver unclassified drug anisotropy article electromagnetic field illumination light scattering P wave polarization priority journal scanning electron microscopy spectroscopy transmission electron microscopy We present a method for sizing metallic nanowires through the analysis of the extinction spectra of the scattered light when the wires are illuminated alternatively with p- and s-polarization waves. The method is applied to isolated silver nanowires in air or immersed in index matching oil. The dielectric function of silver is affected by the size of the cylinders, and its influence on the extinction spectra near the plasmon resonance or near the dip position is considered. Due to the size of the nanocylinders, it is necessary to include two different permittivities in the electromagnetic model to analyse the behaviour of the material under different polarization incidences. This introduces anisotropy in the system, which comprises isotropic cylinders. The behaviour of the extinction spectra for p-waves allows us to determine the wire radii, taking into account the plasmon peak position for radii larger than 7 nm, or alternatively, by using the contrast between maximum and minimum intensity near the plasmon frequency, for radii lower than 5 nm. For s-waves, although no plasmon peak appears, we can determine the radii by analysing the contrast between the ridge of the spectra near 260-275 nm and the minimum near 320-330 nm for radii larger than 10 nm, or analysing the slope in the spectra over 350 nm, for radii below 10 nm. The present study shows that spectral extinction is a very simple and inexpensive technique that can be useful for characterizing the radius of nanocylinders when electron microscopy (TEM or SEM) is not available. © IOP Publishing Ltd. Fil:Lester, M. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Skigin, D. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. 2007 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09574484_v18_n31_p_Scaffardi http://hdl.handle.net/20.500.12110/paper_09574484_v18_n31_p_Scaffardi |
| institution |
Universidad de Buenos Aires |
| institution_str |
I-28 |
| repository_str |
R-134 |
| collection |
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) |
| topic |
Electromagnetic model Index matching oil Optical extinction spectroscopy Plasmon peak position Polarization incidences Light polarization Light scattering Permittivity Spectroscopic analysis Surface plasmon resonance Transmission electron microscopy Nanowires metallic nanowire nanowire silver unclassified drug anisotropy article electromagnetic field illumination light scattering P wave polarization priority journal scanning electron microscopy spectroscopy transmission electron microscopy |
| spellingShingle |
Electromagnetic model Index matching oil Optical extinction spectroscopy Plasmon peak position Polarization incidences Light polarization Light scattering Permittivity Spectroscopic analysis Surface plasmon resonance Transmission electron microscopy Nanowires metallic nanowire nanowire silver unclassified drug anisotropy article electromagnetic field illumination light scattering P wave polarization priority journal scanning electron microscopy spectroscopy transmission electron microscopy Lester, Marcelo Skigin, Diana Carina Optical extinction spectroscopy used to characterize metallic nanowires |
| topic_facet |
Electromagnetic model Index matching oil Optical extinction spectroscopy Plasmon peak position Polarization incidences Light polarization Light scattering Permittivity Spectroscopic analysis Surface plasmon resonance Transmission electron microscopy Nanowires metallic nanowire nanowire silver unclassified drug anisotropy article electromagnetic field illumination light scattering P wave polarization priority journal scanning electron microscopy spectroscopy transmission electron microscopy |
| description |
We present a method for sizing metallic nanowires through the analysis of the extinction spectra of the scattered light when the wires are illuminated alternatively with p- and s-polarization waves. The method is applied to isolated silver nanowires in air or immersed in index matching oil. The dielectric function of silver is affected by the size of the cylinders, and its influence on the extinction spectra near the plasmon resonance or near the dip position is considered. Due to the size of the nanocylinders, it is necessary to include two different permittivities in the electromagnetic model to analyse the behaviour of the material under different polarization incidences. This introduces anisotropy in the system, which comprises isotropic cylinders. The behaviour of the extinction spectra for p-waves allows us to determine the wire radii, taking into account the plasmon peak position for radii larger than 7 nm, or alternatively, by using the contrast between maximum and minimum intensity near the plasmon frequency, for radii lower than 5 nm. For s-waves, although no plasmon peak appears, we can determine the radii by analysing the contrast between the ridge of the spectra near 260-275 nm and the minimum near 320-330 nm for radii larger than 10 nm, or analysing the slope in the spectra over 350 nm, for radii below 10 nm. The present study shows that spectral extinction is a very simple and inexpensive technique that can be useful for characterizing the radius of nanocylinders when electron microscopy (TEM or SEM) is not available. © IOP Publishing Ltd. |
| author |
Lester, Marcelo Skigin, Diana Carina |
| author_facet |
Lester, Marcelo Skigin, Diana Carina |
| author_sort |
Lester, Marcelo |
| title |
Optical extinction spectroscopy used to characterize metallic nanowires |
| title_short |
Optical extinction spectroscopy used to characterize metallic nanowires |
| title_full |
Optical extinction spectroscopy used to characterize metallic nanowires |
| title_fullStr |
Optical extinction spectroscopy used to characterize metallic nanowires |
| title_full_unstemmed |
Optical extinction spectroscopy used to characterize metallic nanowires |
| title_sort |
optical extinction spectroscopy used to characterize metallic nanowires |
| publishDate |
2007 |
| url |
https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09574484_v18_n31_p_Scaffardi http://hdl.handle.net/20.500.12110/paper_09574484_v18_n31_p_Scaffardi |
| work_keys_str_mv |
AT lestermarcelo opticalextinctionspectroscopyusedtocharacterizemetallicnanowires AT skigindianacarina opticalextinctionspectroscopyusedtocharacterizemetallicnanowires |
| _version_ |
1768544143924002816 |