Fig. 1 Two-dimensional pit model of quartz glass surface More about this image found in Two-dimensional pit model of quartz glass surface

Fig. 2 Mechanism of changes in wetting state of quartz glass surface: ( a ) when the linear velocity is low, it is in a hydrophilic state; ( b ) transition state after increasing linear velocity; and ( c ) at high linear velocity, it is in a hydrophobic state More about this image found in Mechanism of changes in wetting state of quartz glass surface: ( a ) when t...

Fig. 3 Material selective removal More about this image found in Material selective removal

Fig. 4 Maintenance analysis of droplet residence state More about this image found in Maintenance analysis of droplet residence state

Fig. 5 Measurement results of droplet size More about this image found in Measurement results of droplet size

Fig. 6 Some observation results of CCD camera (number of injection changes from 13 to 16) More about this image found in Some observation results of CCD camera (number of injection changes from 13...

Fig. 7 Resident droplet surface chemical finishing setup More about this image found in Resident droplet surface chemical finishing setup

Fig. 8 Minimum spindle speed at droplet residence state occurs with different surface roughness More about this image found in Minimum spindle speed at droplet residence state occurs with different surf...

Fig. 9 High-speed camera recording of droplets approaching a stationary wall: ( a ) contact wall surface, t  = 0 s; ( b ) t  = 0.02 s; and ( c ) t  = 0.04 s More about this image found in High-speed camera recording of droplets approaching a stationary wall: ( a ...

Fig. 10 Experimental image of liquid droplets approaching the wall: ( a ) 4000 rpm, droplet adsorption; ( b ) 20,000 rpm, droplet residence; and ( c ) 20,000 rpm, droplet break up and splashing More about this image found in Experimental image of liquid droplets approaching the wall: ( a ) 4000 rpm,...

Fig. 11 Schematic diagram of layered overlap method More about this image found in Schematic diagram of layered overlap method

Fig. 12 Comparison of surface before and after resident droplet surface chemical finishing: ( a ) before resident droplet surface chemical finishing (case D, Sa 146 nm) and ( b ) after resident droplet surface chemical finishing (case D, Sa 74 nm) More about this image found in Comparison of surface before and after resident droplet surface chemical fi...

Fig. 13 Experimental results of droplet residence chemical finishing (same processing time) More about this image found in Experimental results of droplet residence chemical finishing (same processi...

Fig. 14 Experimental results of resident droplet surface chemical finishing (processing to wetting state change) More about this image found in Experimental results of resident droplet surface chemical finishing (proces...

Fig. 1 Functional scheme of the aerosol jet printing process More about this image found in Functional scheme of the aerosol jet printing process

Fig. 2 Comparison of the estimated Reynolds numbers and possible nozzle distances in the AJP method with laminar lengths of jets with different Reynolds numbers determined from the literature [ 8 – 11 ] More about this image found in Comparison of the estimated Reynolds numbers and possible nozzle distances ...

Fig. 3 Numerical simulated mean axial velocity decay around the centerline of a jet ( Re = 3461 ) [ 19 ] More about this image found in Numerical simulated mean axial velocity decay around the centerline of a je...

Fig. 4 Comparing normalized flow velocity and turbulence intensity ( Tu ≡ I ) of a jet ( Re = 3461 ) between measured and numerical values [ 19 ] More about this image found in Comparing normalized flow velocity and turbulence intensity ( Tu ≡ I ...