Add to ORKGIn this paper, we analyze the performance of an electro-optic modulator based on a single quantum dot strongly coupled to a nanoresonator, where electrical control of the quantum dot frequency is achieved via quantum confined Stark effect. Using realistic system parameters, we show that modulation speeds of a few tens of GHz are achievable with this system, while the energy per switching operation can be as small as 0.5 fJ. In addition, we study the non-linear distortion, and the effect of pure quantum dot dephasing on the performance of the modulator
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
In this paper, we analyze the performance of an electro-optic modulator based on a single quantum do...
In this paper, we analyze the performance of an electro-optic modulator based on a single quantum do...
The resonance frequency of an InAs quantum dot strongly coupled to a GaAs photonic-crystal cavity wa...
The reflectivity of a photonic crystal cavity is modified using a single coupled quantum dot. We dem...
Abstract. The linear electro-optic properties in waveguides containing self-organized InAs quantum d...
The electro-absorption properties and Stark-shift of 1.3μm InGaAs quantum dot waveguide modulators a...
The low voltage modulation in InAs quantum dot waveguides is observed in this paper. We have measure...
The low voltage modulation in InAs quantum dot waveguides is observed in this paper. We have measure...
The low voltage modulation in InAs quantum dot waveguides is observed in this paper. We have measure...
The linear electro-optic properties in waveguides containing self-organized In As quantum dots were ...
The linear electro-optic properties in waveguides containing self-organized In As quantum dots were ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
In this paper, we analyze the performance of an electro-optic modulator based on a single quantum do...
In this paper, we analyze the performance of an electro-optic modulator based on a single quantum do...
The resonance frequency of an InAs quantum dot strongly coupled to a GaAs photonic-crystal cavity wa...
The reflectivity of a photonic crystal cavity is modified using a single coupled quantum dot. We dem...
Abstract. The linear electro-optic properties in waveguides containing self-organized InAs quantum d...
The electro-absorption properties and Stark-shift of 1.3μm InGaAs quantum dot waveguide modulators a...
The low voltage modulation in InAs quantum dot waveguides is observed in this paper. We have measure...
The low voltage modulation in InAs quantum dot waveguides is observed in this paper. We have measure...
The low voltage modulation in InAs quantum dot waveguides is observed in this paper. We have measure...
The linear electro-optic properties in waveguides containing self-organized In As quantum dots were ...
The linear electro-optic properties in waveguides containing self-organized In As quantum dots were ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...
Photonic switches require low-loss polarization-independent phase-shifting elements. In a composite ...