Abstract
Precision measurements of a nanoscale sample surface using an atomic force microscope (AFM) require a precise quantitative knowledge of the 3D tip shape. Blind tip reconstruction (BTR), established by Villarrubia, gives an outer bound with larger errors if the tip characterizer is not appropriate. In order to explore the errors of BTR, a series of simulation experiments based on a conical model were carried out. The results show that, to reconstruct the tip precisely, the cone angle of the tip characterizer must be smaller than that of the tip. Furthermore, the errors decrease as a function of the tip cone angle and increase linearly with the sample radius of curvature, irrespective of the tip radius of curvature. In particular, for sharp (20 nm radius) and blunt (80 nm radius) tips, the radius of curvature of the tip characterizer must be smaller than 5 nm. Based on these simulation results, a local error model of BTR was established. The maximum deviation between the errors derived from the model and the simulated experiments is 1.22 nm. Compared with the lateral resolution used in the above simulated experiments (4 nm/pixel), it is valid to ignore the deviations and consider the local error model of BTR is indeed in quantitative agreement with the simulation results. Finally, two simulated ideal structures are proposed here, together with their corresponding real samples. The simulation results show they are suitable for BTR.
Highlights
Atomic force microscope (AFM) is the most prevalent technique for studying the surface properties of materials from the micron all the way down to the atomic level in a variety of science and technology areas
Some limitations caused by the geometry of the scanning tip degrade the accuracy of the AFM images which are distorted by the dilation effect between the tip and the actual sample surface [4,5,6]
Resembling the foregoing discussions, Pr is only equal to those segments of P that have been in contacted with the sample surface but an upper bound elsewhere
Summary
Atomic force microscope (AFM) is the most prevalent technique for studying the surface properties of materials from the micron all the way down to the atomic level in a variety of science and technology areas. Some limitations caused by the geometry of the scanning tip degrade the accuracy of the AFM images which are distorted by the dilation effect between the tip and the actual sample surface [4,5,6]. Representation [36,37] This algorithm can reconstruct an upper bound of the tip shape from an AFM image obtained by scanning any samples. In order to determine the real sample surface geometry, it is better to obtain a more accurate 3D tip shape, i.e., the minimum upper bound by using the suitable tip characterizer. The results show that this kind of structures is a suitable tip characterizer
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