Methods The optical properties of gold nanoparticles are solved n

Methods The optical properties of gold nanoparticles are solved numerically in the frequency domain using the click here scattered field formulation. Field analysis was performed using a commercially available finite-element-method package (COMSOL Multiphysics 4.3a). The simulation method has been well documented in [21–23]. The extinction cross section is simply defined as the sum of absorption and scattering cross Selleck Emricasan sections of the nanoparticles. More specifically, the dielectric function of gold used in the simulations is extracted by interpolation of

Johnson and Christy’s results [24], and the nanoparticles are placed in a homogeneous medium resembling water, whose RI can be changed from 1.33 to 1.37 for comparison. Results and discussion Multipolar plasmonic modes in gold nanorods Excitations of plasmonic higher order modes such as quadrupole and

sextupole resonances in metallic nanoparticles require a particular incident angle and polarization state. Figure 1a shows an angle-dependent excitation of a gold nanorod (length 500 nm, diameter 40 nm) in water (n = 1.33) by a TM-polarized plane wave. Figure 1 Extinction characteristics of a gold nanorod in water ( n  = 1.33). (a) The configuration of the numerical modeling. (b) Simulated extinction spectra of the gold nanorod for different incident angles θ; the extinction LY2090314 datasheet value in the left panel is normalized to the quadrupole peak for θ = 45°, and in the right panel to the dipole peak for θ = 0° (with a scale 3.36 times larger than the left panel). Curves are plotted with offset for clarity. (c) Angle-dependent peak extinction for the dipole, quadrupole, and sextupole resonance modes, normalized to the maximum values of each mode. Figure 1b renders the extinction spectra of a gold nanorod at different excitation angles, which show three distinct extinction peaks, namely a dipole resonance at 2,060 nm, a quadrupole resonance at 1,030 nm, and a sextupole resonance at 734 nm, respectively. The mode nature of these three extinction resonances is unambiguously confirmed

respectively by their near-field Dolichyl-phosphate-mannose-protein mannosyltransferase distribution (electric field amplitude) and far-field radiation patterns, as shown in Figure 2. The extinction spectra shown in Figure 1b also reveal that each resonance has an optimal excitation angle at which the extinction cross section is a maximum. The normalized extinction intensity for each resonance is plotted as a function of the incident angle as shown in Figure 1c. As expected, the dipole resonance is efficiently excited when the incident polarization is parallel to the nanorod axis. Interestingly, the quadrupole mode responds most strongly to an incident angle at 40°, while the sextupole mode shows double maxima at excitation angles of 0° and 55°. In fact, these optimal angles correspond, respectively, to the maximum near-field amplitude and far-field radiation power for each resonance presented in Figure 2.

Comments are closed.