Congratulations to New ICFO PhD Graduate
Dr. Jennifer Aldama graduated with a thesis entitled ‘Toward integrating continuous-variable quantum key distribution technology’
We congratulate Dr. Jennifer Aldama who defended her thesis today in ICFO’s Auditorium.
Dr. Jennifer Aldama obtained her MSc in Physics at the University of Puerto Rico. She joined the Optoelectronics research group at ICFO led by ICREA Prof. Dr. Valerio Pruneri as a PhD student.
Dr. Aldama’s thesis entitled ‘Toward integrating continuous-variable quantum key distribution technology’ was supervised by ICREA Prof. Dr. Valerio Pruneri and Dr. Sebastián Etcheverry Cabrera.
ABSTRACT:
Being able to secure confidential information is imperative in today’s society, but advancements in quantum technologies pose a potential threat. In response, researchers are developing technologies based on quantum mechanics, such as quantum key distribution (QKD), in particular continuous-variable QKD (CV-QKD), which is emerging as a promising solution due to its compatibility with classical network infrastructures. However, current systems remain bulky and costly, limiting their widespread adoption. To address this challenge, the miniaturization and integration of QKD systems into monolithic photonic integrated circuits (PICs) have the potential to accelerate adoption across a broader market. This is due to the anticipated reductions in size, power consumption, production costs and overall system complexity.
This work presents four pulsed Gaussian-modulated coherent state (GMCS) CV-QKD systems based on discrete components and, in the last case, a PIC. The thesis begins with a modular system utilizing discrete components, such as phase and amplitude modulators. Notably, this prototype eliminates the need for phase locking, as the same laser serves as both a local oscillator and the source for generating quantum signals. The system mitigates Rayleigh backscattering by employing two channels, one for transmitting light and the other for transmitting coherent states. Demonstrations indicate its operability over metropolitan distances.
In the second approach, the system showcases the parallelization of CV-QKD signals and the coexistence of multiple quantum signals with a classical signal, spatially multiplexed through a multicore fiber (MCF). In this scenario, two lasers are employed, with one emitting the frequency locking signal propagating along one of the MCF’s core.
The third proposal introduces a simplified CV-QKD transmitter (TX) that eliminates the need for a phase modulator in the GMCS generation. This system leverages the random properties of a distributed feedback (DFB) laser operating in the gain-switching (GS) mode. The study demonstrates the applicability of our proposed compact TX for GMCS generation in CV-QKD and its feasibility for integration into a metropolitan network.
Finally, we describe and characterize an InP-based PIC TX tailored for CV-QKD applications. System-level proof-of-principle experiments are conducted using a shared laser approach with a pulsed GMCS CV-QKD protocol over an 11 km optical fiber channel. The results indicate potential secret key rates of 52 kbps in the asymptotic regime and 27 kbps in the finite size regime, highlighting the capabilities of the proposed PIC design and, more broadly, the properties of InP technologies for monolithic integration of CV-QKD systems. All the proof-of-principle experiments outlined in this dissertation contribute significantly to the field of miniaturizing CV-QKD systems.
Thesis Committee:
Prof. Dr. María Concepción Santos Blanco, Universitat Politècnica de Catalunya
Dr Matteo Schiavon, Sorbonne University
Dr Laura Ortiz Martín, ETS. Ingenieros Informáticos