Scanning electron microscope images

Fig. 51. Scanning electron microscope image of different stages of metalization of DNA. (a) Linear chain of separated palladium clusters connecting two gold contacts (b) magnification of (a) showing clusters with diameter > 40 nm (c) continuous coated DNA strand after one development step with a diameter larger than 40 nm. Reproduced with permission from Ref. (175). Copyright 2001, American Institute of Physics.

Figure 3.14 Scanning electron microscope image of a tip etched by the lamellae drop-off etching technique. (Reproduced from Ref. 35).

Figure 4. Scanning electronic microscope images (x5000) of (a) parent PET film (b) PET film treated in DMF at 140°C for 13 min (c) 10.5 pHEKA containing PET film.

Nanotubes of tin (Scanning electron microscope image by S. Schlecht, Freie Universitat Berlin. Reprinted form Angewandte Chemie 118 (2006) 317, with permission from Wiley-VCH)... 

The physical characteristics of the powder and the mechanical properties of the electrode made from these powders were seen to be among key important parameters. Some physical characteristics of the LBG1025 and its typical Scanning Electron Microscope image can be found in Table 3. The SEM shows a flaky, rounded edge smooth morphology. 

Table 3. Physical characteristics and typical Scanning Electron Microscope image of purified natural graphite LBG1025.

Figure 3. Scanning Electron Microscope Images of thermally purified natural crystalline flake graphite 2900G (a), and its ground versions displaying platelet (b) and spheroidal (c) morphologies.

Fig. 13.3 Scanning electron microscopic images of LDH particles with various size (A) 100, (B) 200, (C) 1500, and (D) 4500 nm. LDH particles (A) and (B) were synthesized under hydrothermal conditions and (C) and (D) were prepared using hydrolysis of urea (see Table 13.1).

Figure 12.4. Left—Scanning electron microscope image of the input/output pads of a silicon IC bumped with eutectic lead/tin solder after solder reflow. Right—Photograph of printed wiring board interconnect pads that have been printed with lead/tin solder prior to reflow.

Fig. 18.5 Scanning electron microscope images showing cross sections of ARROWS with (a) trapezoidal geometry formed from an aluminum core, (b) rectangular geometry formed from an SU8 core, and (c) arched geometry formed from a reflowed photoresist core...

Fig. 18.7 Scanning electron microscope images showing interfaces between solid core and hollow core waveguides, (a) Top view of the interface at the end of a hollow core waveguide, (b) Side view of a solid core waveguide intersecting a hollow core waveguide...

Figure 3. Scanning electron microscope images of a V53-Ti26-Ni21 alloy (a) back-scattered and (b)...

Scanning electron microscope image of a Ti DL with 25 pm diameter holes (reference bar indicates 100 pm). (Reprinted from K. D. Fushinobu et al. Journal of Power Sources 158 (2006) 1240-1245. With permission from Elsevier.)... 

Fig. 5 Scanning electron microscope images for LDHs synthesized by the urea method with a aging times 6, 30, 45, and 69 h, and b the concentration of metal ions, 0.87, 0.65, 0.44, and 0.06 M (scale bar = 2.5 jjim). Reprinted with permission from [76], Copyright...

SEM(Scanning Electron Microscope) image of a silicon relief pattern... 

Fig. 8 Scanning electron microscope images of a photonic crystal formed by macroporous silicon obtained on n-type Si (after Pavesi etal. [10]).

Figure 1.1 Scanning electron microscope image of dried, mono-disperse silica colloids.

Martens and Thybo (2000) used digital image analysis of scanning electron microscope images of potato tissue and of starch to successfully relate microstmcture characteristics to textural properties. 

Figure 3.5 Scanning electron microscope images of the surfaces of (a) a bare carbon fiber microelectrode and (b) a multiwalled carbon nanotube -[C4CjIm][PF ]-modified carbon fiber microelectrode. (Reprinted from Liu, Y., Zou, X., and Dong, S., Electrochem. Commun., 8,1429-1434,2006. Copyright 2006 Elsevier. With permission.)...

Figure 6.2 Picture of a gecko foot (left) and scanning electron microscope images of different resolution of setae (middle) and spatulae (right). Images were kindly provided by K. Autumn.

Figure 7.17 Nanotubes fabricated by letting a precursor film of polystyrol enter the cylindrical pores of filter [288], A schematic of the two main steps in the fabrication process (left) and a scanning electron microscope image (right) are shown. Thanks to M. Steinhard for providing us with the picture.

Figure 10.1 Scanning electron microscope image of a roughly 10 /rm thick CVD diamond film exposing its (001) facets at the top. The image was kindly provided by X. Jiang [414].

Figure 10.13 Scanning electron microscope image of the cantilever array, fabricated by Nanoink Inc., used for the domain writing the insert shows an enlarged view of a single tip at the end of a cantilever.

Figure 10.13. Scanning electron microscope image of porous structure after dissolving away the latex from the latex-gold composite. The scale bar at the bottom right of the image corresponds to 1 pm. (With permission from Ref. 38.)...

Fig. 3 Scanning electron microscope image of a typical mesoscopic Ti02 film employed in DSC. Note the bipyramidal shape of the particles having (101) oriented facets exposed. The average particle size is 20 nm...

Fig. 17. Scanning Electron Microscope image of a ferrofluid emulsion...

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