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Beilstein J. Nanotechnol. 2020, 11, 1126–1133, doi:10.3762/bjnano.11.97
Figure 1: Experimental chamber and laser-induced heating. (a) Chamber cross section. A 5 μm thick liquid laye...
Figure 2: Thermo-optical trapping of a 200 nm polystyrene particle in water (Plas = 44 mW). (a) 2D histogram ...
Figure 3: Simulation results: (a) Trapping potential in x- and y-directions, calculated from the simulated mo...
Figure 4: Example of a tailored nanoparticle trap. Preset feedback rules result in a creation of a 20 × 10 μm2...
Figure 5: Manipulation of a 200 nm nanoparticle in water. (a) The trajectory of the particle. (b) Time depend...
Figure 6: Independent manipulation of two 200 nm particles in water. (a) Particle trajectories. (b) Time depe...
Beilstein J. Nanotechnol. 2012, 3, 163–171, doi:10.3762/bjnano.3.16
Figure 1: The artificial cilium is made of superparamagnetic beads. An external magnetic field is used to act...
Figure 2: Fluid flow around a beating artificial cilium. The cilium was anchored to the surface at (0,0) and ...
Figure 3: The time- and position-averaged flow velocities that were obtained for a variety of beating paramet...
Figure 4: Calculated fluid flow around a beating cilium in the far-field approximation. Blue arrows indicate ...
Figure 5: Magneto-optical tweezers used in the experiment. Three pairs of water-cooled coils ensured an almos...