To fabricate the samples used for this work, DNA https://www.selleckchem.com/products/Fedratinib-SAR302503-TG101348.html strands were deposited on a silicon nitride grid surface. These DNA strands were used as biomolecular templates for the self-assembly of gold nanoparticles [4].

These samples were acquired from Dune Sciences (Eugene, OR, USA). The fabrication process was described elsewhere, and it is not included here because this process is not the aim of this work. Results and discussion Figure 1 shows the results of the LSPR analysis performed on a 26-nm gold spherical nanoparticle linked through DNA strands to a silicon nitride membrane. The top-right corner inset in (a) shows a high-angle annular dark-field (HAADF) image of the area where the SI was acquired including the gold spherical nanoparticle. Two representative EELS spectra marked by the two colored dots are displayed in the chart. The raw data extracted from the SI are displayed

using dotted lines. After applying PCA, the results are shown using dashed lines with long dashes. The result after ZLP subtraction is shown as dashed lines with medium-sized dashes. The difference between the data after PCA reconstruction and the ZLP fit is displayed in the chart using dashed lines with small dashes. The Gaussian fit function is shown with solid lines. Energy loss and amplitude maps are shown in Figure 1b,c. The chart in (b) uses a color-scale that goes from blue as the lowest energy value to red as the highest one. The chart in (c) uses a color-scale that ranges from black, through red and yellow to white EPZ015938 as the highest amplitude value for the fitted Gaussian. Figure 1 Electron energy loss spectra (a) and energy loss (b) and amplitude (c) maps. (a) Electron energy loss spectra of a 26-nm gold nanosphere linked through DNA strands to a Si3N4 membrane; the inset shows an HAADF image of the nanoparticle. The spectrum marked as (curve i) shows the energy loss along the trajectory marked with a red dot where a resonance peak can be clearly seen at 2.4 eV, the one marked as (curve ii) shows the peak at 2.5 eV approximately corresponding to the ZD1839 ic50 trajectory

through the nanoparticle marked with the blue dot. (b) Energy loss map displaying the value of the center of the fitted Gaussian to the LSPR peak. (c) Amplitude map with the intensity value of the center of the fitted Gaussian to the LSPR peak. Both the energy map and the spectrum labeled in red as (curve i) show a very distinct peak at 2.4 eV, this is the typical value for a dipolar LSPR mode in a gold nanoparticle of this size in air [15, 16]. To selleck compound validate the results, the Mie theory has been used to solve the Maxwell equations using both the quasistatic approximation and solving the full Maxwell equations. A 26-nm gold sphere standing in vacuum was considered yielding both approximations a result of 2.44 eV for the extinction of light with the absorption as the main contribution over scattering which corresponds for a metal nanoparticle of this size [1].