Wang et al. [15] used the AFM-based repeated scratching method to obtain nanochannels on the silicon oxide surface. From these previous studies, it can be found that the AFM-based nanomechanical method is feasible for machining nanochannels. However, they were only able to fabricate V-shaped nanochannels or quadrate holes. Recently, Arda Gozen et al. [16, 17] developed a nanomilling system with an AFM tip as the small cutting tool to fabricate the three-dimensional and ladder-shaped nanostructures, which is similar to the traditional milling process. In our previous study [18], a width controllable millimeter-scale nanochannel array was also obtained by a modified AFM-based nanomachining system and

the machined nanochannel showed a consistent depth. However, if a nanochannel learn more with ladder structures Alisertib in vitro at the bottom is needed, the stages must be controlled to reposition for secondary SB273005 processing [16, 18] or the normal load applied on the sample must be varied in the scratching process [19]. The reposition of the stage for secondary processing is less efficient especially for large-scale microstructures using the AFM tip-based nanofabrication method. In addition, the normal load must be controlled all the time

according to the movement trajectory of the AFM tip during the whole machining process to obtain a nanochannel with ladder structure at the bottom, which is relatively complicated for the nanochannel fabrication. Therefore, in this letter, we present

a novel and easy AFM-based nanomanufacturing method combining the AFM internal tip scanning cycles with the high-precision stage movement to Urease fabricate nanochannels with ladder nanostructure at the bottom. Using this method, a nanochannel with ladder nanostructure at the bottom can be achieved by continuous scanning with a fixed scan size. Different structures can be obtained according to the matching relation of the feeding velocity of the tip and the moving velocity of the precision stage. As such, this nanomachining method has the potential to advance the AFM tip-based nanomanufacturing by increasing the removal speed, simplifying the processing procedure, and achieving the large-scale nanofabrication. Methods Figure 1a shows the schematic of the modified AFM-based nanomachining system. The experimental setup mainly includes a commercial AFM (Q-Scope 250; Ambios Company, Santa Cruz, CA, USA) and two high-precision stages (M511.HD; PI Company, Eschbach, Germany). The detail information of the experimental facilities can be found in [18]. The AFM tip used for all nanoscratching tests is a diamond tip (DNISP; Veeco Instruments Inc., Plainview, NY, USA). This tip is a three-sided pyramidal diamond tip (Figure 1b) with a radius R of 85 nm evaluated by the blind reconstruction method [20]. The cantilever of the probe is made of stainless steel with a calibrated normal spring constant K of 174 N/m provided by the manufacturer.