Wavelength- and time-division multiplexing via pump current variation of a pulsed semiconductor laser -- a method of synchronization for quantum key distribution

TL;DR

This paper presents a novel method using pump current variation in pulsed semiconductor lasers to achieve wavelength and time-division multiplexing, enabling synchronization in quantum key distribution systems.

Contribution

It introduces a new approach to tune laser wavelength via pump current variation, facilitating simultaneous qubit generation and synchronization pulses for quantum communication.

Findings

Wavelength tuning is possible through pump current variation at high thermal resistance.

Numerical simulations and experiments confirm the method's effectiveness.

The approach enables improved synchronization in quantum key distribution.

Abstract

The dependence of the semiconductor laser wavelength on the pump current is a well-known phenomenon, which is generally attributed to a change in the refractive index of the active layer due to carrier injection. This effect is usually considered to be a drawback as it causes frequency chirping of the pulses produced via direct current modulation. Here, we show that at high values of thermal resistance of a laser diode, the lasing wavelength is red-shifted due to the change of the refractive index caused by a thermal effect and this shift may significantly exceed (in absolute value) the blue shift related to a refractive index change induced by the carrier injection. We propose to benefit from the ability to tune wavelength by the pump current variation and use the same laser to generate qubits and synchronization optical pulses for quantum key distribution at different wavelengths. To demonstrate the proposed method of synchronization, we perform numerical simulations as well as proof-of-principle experiments.