A temporal Kerr cavity soliton (CS) is an optical pulse that propagates undistributed in a low-loss passive resonator. As part of its energy periodically escapes the resonator at each roundtrip, it forms a pulse train. Owing to th...
A temporal Kerr cavity soliton (CS) is an optical pulse that propagates undistributed in a low-loss passive resonator. As part of its energy periodically escapes the resonator at each roundtrip, it forms a pulse train. Owing to their ultra-high stability compared to the pulses generated by mode-locked lasers, CSs are expected to play a crucial role in the future of atomic clocks, frequency combs, and high-precision metrology. Besides their inherent stability, they exhibit particle-like behavior. In particular, a couple of CSs can interact in the resonator and eventually form a bound state. Depending on the interaction, such coupled states can be more robust than the single-CS state itself. The aim of SITES (Solitons in time-multiplexed resonators) is to study, theoretically and experimentally, how temporal couplings within an optical resonator lead to the emergence of dynamic behaviors and cavity solitons that do not occur otherwise. On the applied side, SITES can give rise to a new kind of ultra-stable pulse train. On the fundamental front, SITES aims to investigate how these couplings between CSs can be leveraged for computational purposes and used to simulate specific crystal lattices. Such synthetic lattice combined with particle-like CSs leads to a fertile ground for the investigation of nonlinear effects in bosonic systems. Despite these strong fundamental and applied reasons, versatile couplings between multiple CSs have not been experimentally explored so far, mainly because the significant losses arising from the couplings prohibit reaching the intriguing nonlinear regimes. The experimental approach of SITES will overcome such a challenge and enables the realization of previously inaccessible coupled CSs.ver más
Seleccionando "Aceptar todas las cookies" acepta el uso de cookies para ayudarnos a brindarle una mejor experiencia de usuario y para analizar el uso del sitio web. Al hacer clic en "Ajustar tus preferencias" puede elegir qué cookies permitir. Solo las cookies esenciales son necesarias para el correcto funcionamiento de nuestro sitio web y no se pueden rechazar.
Cookie settings
Nuestro sitio web almacena cuatro tipos de cookies. En cualquier momento puede elegir qué cookies acepta y cuáles rechaza. Puede obtener más información sobre qué son las cookies y qué tipos de cookies almacenamos en nuestra Política de cookies.
Son necesarias por razones técnicas. Sin ellas, este sitio web podría no funcionar correctamente.
Son necesarias para una funcionalidad específica en el sitio web. Sin ellos, algunas características pueden estar deshabilitadas.
Nos permite analizar el uso del sitio web y mejorar la experiencia del visitante.
Nos permite personalizar su experiencia y enviarle contenido y ofertas relevantes, en este sitio web y en otros sitios web.