This search combines search strings from the content search (i.e. "Full Text", "Author", "Title", "Abstract", or "Keywords") with "Article Type" and "Publication Date Range" using the AND operator.
Beilstein J. Nanotechnol. 2011, 2, 85–98, doi:10.3762/bjnano.2.10
Figure 1: Evolution of the logarithm of the dissipated power normalized by the radius (R) as a function of (a...
Scheme 1: Scheme presenting the different forces during tip–particle and particle–substrate interactions, and...
Figure 2: Typical trajectories of bare gold nanoparticles (20 nm diameter) on a silicon substrate when the pr...
Figure 3: Typical scan patterns used in AFM: (a) raster scan path used by Nanosurf (b) zigzag scan path used ...
Figure 4: AFM images of nanocluster movement during their manipulation (a) gold nanorods deposited onto silic...
Figure 5: (a) Average power dissipation accompanying the onset of motion of as-synthesized and coated nanopar...
Figure 6: AFM images of 25 nm diameter gold nanoparticles deposited onto a silicon wafer. (a) Ordered organiz...
Scheme 2: Formation of two capillary water bridges between hydrophilic tip and particle, and particle and sur...
Scheme 3: Formation of two water layer films between hydrophilic tip–hydrophobic particle, and hydrophobic pa...
Figure 7: As-synthesized Au particles on silicon in ultra-high vacuum. Frame size: 3 µm.
Figure 8: AFM image of nanopatterned surface exhibiting Si pits: Frame size: 3 µm.
Figure 9: Manipulation of as-synthesized Au nanoparticles on (a) a flat silicon wafer with a spacing of 9.7 n...
Figure 10: Logarithm of the dissipated power in moving as-synthesized NPs on silicon wafer versus the tip scan...
Figure 11: 400 nm × 400 nm TEM image of 25 nm diameter gold nanoparticles.