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Beilstein J. Nanotechnol. 2014, 5, 419–437, doi:10.3762/bjnano.5.50
Figure 1: Geometry of the deformed tip (upper grey solid), the substrate (lower solid), and the reference tip...
Figure 2: (a) Finite-range surface energies and (b) forces per unit area for the models investigated in this ...
Figure 3: Scaled gap g(r) as a function of scaled distance from origin r for two different parameter realizat...
Figure 4: Negative elastic displacement −u(r) (as defined in Figure 1) of a tip with R = E = 1 pressed against a rigi...
Figure 5: Interfacial pressure on a free, linearly-elastic half space resting at zero external load on a rigi...
Figure 6: Gap between a rigid, adhesive, parabolic tip and a linearly-elastic half space for two different Ta...
Figure 7: Pressure p(r) in the Gauss model at zero load for two different Tabor coefficients as a function of...
Figure 8: Gap g(r) in linear (a) and logarithmic (b) representation as well as (c) first derivative g′(r) for...
Figure 9: Contact radius ac at zero external load as a function of the Tabor coefficient μT for different mod...
Figure 10: Normal displacement d at zero external load as a function of the Tabor coefficient μT for different...
Figure 11: Contact radius ac as a function of load FN for the exponential and the MD model using different Tab...
Figure 12: Normal displacement d as a function of load FL for the exponential and the MD model using different...
Figure 13: Relative errors in per cent for the contact radius ac for μT = 1 at (a) negative and (b) positive l...
Figure 14: Relative errors in per cent for (a) contact radius and (b) normal displacement at zero normal load....
Figure 15: Excess contact radius Δac = ac − ap as a function of the excess load ΔFN = FN + Fp for different va...
Figure 16: Contact radius ac as a function of normal force FN for the exponential (full symbols) and the Gauss...
Figure 17: Contact radius ac as a function of normal force FN in the vicinity of the spontaneous wetting force ...
Figure 18: Displacement d as a function of normal force FN in the vicinity of the spontaneous wetting force Fsw...
Figure 19: Gap g(r) as a function of the lateral distance from the origin r for a large load FN = 60 (a) and (...
Figure 20: Contact geometry for a Gauss model with finite-range repulsion. Arrows indicate the direction of no...