Salim Benadouda Ivars scite author profile

We uncover a novel and robust phenomenon that causes the gradual self-replication of spatiotemporal Kerr cavity patterns in cylindrical microresonators. These patterns are inherently synchronised multi-frequency combs. Under proper conditions, the axially-localized nature of the patterns leads to a fundamental drift instability that induces transitions amongst patterns with a different number of rows. Self-replications, thus, result in the stepwise addition or removal of individual combs along the cylinder's axis. Transitions occur in a fully reversible and, consequently, deterministic way. The phenomenon puts forward a novel paradigm for Kerr frequency comb formation and reveals important insights into the physics of multi-dimensional nonlinear patterns.

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Non-Hermitian management of light in multimode fibers

Akhter¹,

Ivars²,

Herrero³

et al. 2022

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Salim Benadouda Ivars

Non-Hermitian control of optical turbulence in systems with fractional dispersion

Reversible Self-Replication of Spatiotemporal Kerr Cavity Patterns

Non-Hermitian management of light in multimode fibers

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