Figures index

From

An Outlook on Optothermal Human Cancer Cells, Tissues and Tumors Treatment Using Lanthanum Nanoparticles under Synchrotron Radiation

Alireza Heidari, Katrina Schmitt, Maria Henderson, Elizabeth Besana

Journal of Materials Physics and Chemistry. 2019, 7(1), 29-45 doi:10.12691/jmpc-7-1-4
  • Scanning Electron Microscope (SEM) image of Lanthanum nanoparticles with 50000x zoom.
  • Figure 1. Maximum increase in temperature for Lanthanum nanospheres
  • Figure 2. Variations of absorption to extinction ratio and scattering to extinction ratio for Lanthanum nanospheres with various radiuses
  • Figure 3. Maximum increase in temperature for spherical nanoparticles with radius of 45 (nm) at Plasmon wavelength of 685 (nm)
  • Figure 4. Maximum increase in temperature for core–shell Lanthanum nanospheres with various thicknesses of silica shell
  • Figure 5. Maximum increase in temperature for core–shell nanoparticles with radius of 45 (nm) and silica thickness of 10 (nm) at Plasmon wavelength of 701 (nm)
  • Figure 6. Extinction cross section area for Lanthanum nanorods with effective radius of 45 (nm) and various dimension ratios
  • Figure 7. Maximum increase in temperature for nanorods with effective radius of 20 and 45 (nm) and various dimension ratios.