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| Biophotonics (21) | |
| Nanophotonics (38) | |
| Photonic computing (10) | |
| Photonic crystal (42) | |
| Photonic devices (158) | |
| Photonic integrated circuit (11) | |
| Photonic metamaterial (6) | |
| Photonic system (5) | |
| Photonics (149) | |
| Silicon photonics (34) | |
Based on that hypothesis Bob Zheng a graduate student at Rice university set out to design a photonic system that could detect colored light.
LANP graduate student Bob Zheng set out to create a photonic system that could detect colored light but in what lab director Naomi Halas calls a great example of the serendipity that can occur in the lab he wound up with a device with far broader applications.
Photonic systems could eventually replace electronic ones, but the fundamentals of computation, mixing two inputs into a single output, currently require too much space and power when done with light.
Based on that hypothesis LANP graduate student Bob Zheng the lead author of the new Advanced Materials study set out to design a photonic system that could detect colored light.
The rapid development in nano-optics and on-chip photonic systems has increased the demand for ultrathin flat lenses with three-dimensional subwavelength focusing capability the ability to see details of an object smaller than 200 nanometres.
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