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분야
pptx2.Applications
3.Future prospects
Similar to this, photons must overcome the photonic band gap energy to generate the color.
Then, if we know the specific color band gap, we can make that color by control the atomic structures.
Also, we can use this in ‘Information and communications technology’ by controls of total internal reflection.
In the micrometer scales of water, add the nano scales of
coloid.
Then, the coloids are surrounded by water, and they arrange themselves(the form of 3D photonic crystals).
After that, evaporate the water, we can get the photonic
crystals.
If the water replaced with photosensitive liquid, we can save the evaporation time.
A conventional microscope image of Caenorhabditis sample
An optofluidic microscope (700-nm resolution) image of sample.
By staggering the holes along the length of the channel, the separation between holes can be made equal to the pixel size of the underlying sensor array and enable the unique mapping of each hole to a pixel. The lateral displacement of the holes across the channel can be made arbitrarily small and it defines the resolution of the microscope. This approach enables the construction of microscopes with resolutions that are much finer than the pixel resolution of a conventional sensor grid
