2017 results:
1581. Pho­toa­coustics  
Since dif­fe­rent sorts of tis­su­es have dif­fe­rent op­ti­cal ab­sorp­ti­on be­ha­viours, cer­tain sorts of tis­su­es can be…  
1582. Pho­toa­coustics - Pho­toa­coustics  
Pho­toa­coustics Pho­toa­coustics is a tech­ni­que, which com­bi­nes the ad­van­ta­ges of the op­ti­cal ima­ging me­thods with…  
1583. Op­ti­cal Co­he­rence To­mo­gra­phy  
The phy­si­cal prin­ci­ple be­hind OCT is based on low co­he­rence in­ter­fe­ro­me­try. The light which is back­scat­te­red from the…  
1584. Op­ti­cal Co­he­rence To­mo­gra­phy  
Op­ti­cal co­he­rence to­mo­gra­phy: Ap­p­li­ca­ti­ons ex­pand as tech­no­lo­gy ma­tu­res 21 March 2013, SPIE News­room.…  
1585. Op­ti­cal Co­he­rence To­mo­gra­phy - Op­ti­cal Co­he­rence To­mo­gra­phy  
Op­ti­cal Co­he­rence To­mo­gra­phy  
1586. Mo­dern Microsco­py  
Fi­gu­re 3: Star on a 1 € coin  
1587. Mo­dern Microsco­py  
Fi­gu­re 6: 200µm x 200µm se­mi­con­duc­tor samp­le in pho­to­lu­mi­nescence mode  
1588. Mo­dern Microsco­py  
Fi­gu­re 5: 200µm x 200µm se­mi­con­duc­tor samp­le in re­flec­tion mode  
1589. Mo­dern Microsco­py  
An im­portant sub­ject is the ana­ly­sis of se­mi­con­duc­tor ma­te­ri­als, es­pe­ci­al­ly the III/V se­mi­con­duc­tors…  
1590. Mo­dern Microsco­py  
Fi­gu­re 2: Test chart with struc­tu­res of 400nm, 350nm and 300nm size  
Search results 1581 until 1590 of 2017
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