Scanning electron micrograph of negative

Figure 12. Scanning electron micrograph of negative images delineated in poly(TBMA-co-ST) resist at 7.6 mJ/cm2 of 254 nm radiation.

Figure 10. Scanning electron micrographs of negative tone images before (left) and after (right) heating in air at 200 C. for 30 min.

Figure 10. Scanning electron micrographs of negative images obtained by surface modification method using (a) 1, (b) 2b and (c) 4.

Figure 5. Scanning electron micrograph of negative images projection-printed at 0.4 mJ/cm of 248 nm radiation in preliminary tertiary alcohol resist containing...

Figure 10. Scanning electron micrographs of positive (top, 3.5 mJ/cm2) and negative images (bottom, 3.0 mJ/cm2) heated at 200°C for 30 min (the positive image was re-exposed to 2.8 mJ/cm2 of 254 nm radiation and baked at 130 C for 2 min prior to the 200°C bake).

As a first step in our study, we decided to assess our idea of microfabricated nib tips with simple structures based on the negative photoresist SU-8. Structures having a 2/2 D topology were fabricated on a silicon wafer support 11 it should be noted that the nib feature is not completely planar as the tip of the nib tended to point upwards due to stress in the thick SU-8 polymer layer. The nib structure is composed of a reservoir feature, a capillary slot leading the liquid to the tip of the nib where electrospray occurs upon HV application. These first nib prototypes have a microfluidic capillary slot with a width of around 20 pm. Figure 5.2 shows a scanning electron micrograph of a microfabricated nib tip in SU-8 and supported on a silicon support. 

Fig. 3.47. Scanning electron micrograph of crystals within Pb + PbS04 zone during first stage of formation of negative plate [55].

Fig. 3.50. Scanning electron micrograph of lead crystals in charged negative plate after 10 charge-discharge cycles [55].

Fig. 3.52. Scanning electron micrograph of skeleton of discharged negative plate after dissolving PbS04 crystals [55].

Fig. 13 Scanning electron micrographs of positive (top) and negative (bottom) images delineated in fBOC resist by X-ray irradiation [15,16]...

Scanning electron micrograph of lead crystals in a completely formed negative plate [2]. Formation was conducted in H2SO4 solution of 1.05 relative density [2]. 

Scanning electron micrographs of a separator from a wet-charged battery after 9 months of storage. Separator surface facing (a) positive plate (b) negative plate. 

Figure 6. Scanning electron micrographs of the negative image printed in the systems consisting of 1 (a) and 2 (b).

Figure 26 Scanning electron micrograph of clean hair that has been exposed to a negatively charged silica colloid there is no evidence of any deposition of silica particles. (From Refs. 60,61.)... 

Photography, Silver Halides, Fig. 1 A scanning electron micrograph of the section of a layered photo-staisOT in a color negative film, where white lines and spots are the sections of AgX grains. The photo-staisOT is composed of 14 layers with different functions and 20 pm thick in total... 

Photography, Silver Halides, Fig. 2 A scanning electron micrograph of tabular AgX grains developed for highly sensitive layers in a color negative film... 

Figure 15. Scanning electron micrograph illustrating the heterocoagulation of cationic latex particles (diameter = 0.43 fj/n) onto a negatively charged latex particle (diameter = 2.14 pm)...

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