Stopping Light in a Waveguide with an All-Optical Analog<? format?> of Electromagnetically Induced Transparency
We introduce a new all-optical mechanism that can compress the bandwidth of light pulses
to absolute zero, and bring them to a complete stop. The mechanism can be realized in a
system consisting of a waveguide side coupled to tunable resonators, which generates a
photonic band structure that represents a classical analogue of the electromagnetically
induced transparency. The same system can also achieve a time-reversal operation. We
demonstrate the operation of such a system by finite-difference time-domain simulations of …
to absolute zero, and bring them to a complete stop. The mechanism can be realized in a
system consisting of a waveguide side coupled to tunable resonators, which generates a
photonic band structure that represents a classical analogue of the electromagnetically
induced transparency. The same system can also achieve a time-reversal operation. We
demonstrate the operation of such a system by finite-difference time-domain simulations of …
We introduce a new all-optical mechanism that can compress the bandwidth of light pulses to absolute zero, and bring them to a complete stop. The mechanism can be realized in a system consisting of a waveguide side coupled to tunable resonators, which generates a photonic band structure that represents a classical analogue of the electromagnetically induced transparency. The same system can also achieve a time-reversal operation. We demonstrate the operation of such a system by finite-difference time-domain simulations of an implementation in photonic crystals.
American Physical Society以上显示的是最相近的搜索结果。 查看全部搜索结果