The cross-sectional height measured along the A-A’ line shown in

The cross-sectional height measured along the A-A’ line shown in Figure 3d gradually increases, as shown in Figure 3e, which implies that the amount of iron

catalyst deposited through the nanostencil apertures increases with increasing Linsitinib chemical structure aperture diameter. The effect of aperture size on the transferred pattern has previously been demonstrated for metallic nanowire fabrication [31]. In addition, the boundary between neighboring iron catalysts is obscure because of blurring, which could be decreased by decreasing the size of the gap between the stencil and the substrate, decreasing the deposition rate, decreasing the temperature of the substrate during evaporation [39], or by a combination thereof. The boundary of the height profile measured along the

B-B’ line shown in Figure 3f is clearer than that of the height profile measured along the https://www.selleckchem.com/products/xmu-mp-1.html A-A’ line despite blurring since the vertical spacing (350 nm) between each aperture used to deposit the iron catalyst along the B-B’ line is larger than the horizontal spacing (260 nm) along the A-A’ line. The thickness and the average diameter of the iron catalyst patterns deposited through the 177-nm-diameter apertures were 1.6 to 1.7 nm and 449 nm, respectively, which revealed that significant blurring existed during the pattern transfer. Figure 3 Correlation between aperture diameter and deposited iron catalyst. (a) SIM image of the stencil mask fabricated with 1,152 nanoapertures. (b) Tapping-mode AFM image of the iron catalyst deposited nearly onto MK-8776 cell line the substrate through the stencil mask. (c, d) Enlarged SIM and AFM images of the apertures and patterned iron catalyst shown in (a) and (b), respectively. Diameter of the apertures was 60 to 240 nm, and horizontal spacing between apertures was 260 nm. (e, f) Cross-sectional height profiles for iron catalyst deposited along lines indicated by A-A’ and B-B’ in (d). Height of the deposited catalyst increases with increasing diameter of aperture, and thickness of

the iron catalyst deposited through 177-nm aperture is 1.6 to 1.7 nm. The number of CNTs synthesized using CVD and apertures of various diameters was analyzed. Some 21 × 21 apertures whose diameters were 140, 80, or 40 nm were fabricated (Figure 4a) for the experiments, and the spacing between each aperture was 10 μm to prevent any possibility of catalyst pattern interference due to blurring between neighboring apertures, as shown in Figure 4b. The ion doses used during FIB milling to produce the 140-, 80-, and 40-nm apertures were 1.99 × 1018, 9.95 × 1017, and 3.98 × 1017 ions cm−2, respectively. As shown in the scanning electron microscopy (SEM) images in Figure 4c,d,e, the number of CNTs synthesized at a specific location can be controlled by designing the diameter of the nanostencil aperture.

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