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Kovacs-like memory effect mediated fiber Bragg grating: resembling a silica quipu

Qiaochu Yang, Zhiyuan Xu, Xu Yue, Junqiu Long, Haopeng Wang, Yihan Zha, Fu-Rong Feng, Yang Ran, Bai‐Ou Guan

2025Nature Communications9 citationsDOIOpen Access PDF

Abstract

In antiquity, civilizations employed stone carvings and knotted quipu cords for information preservation. Modern telecommunications rely on optical fibers - silica glass strands engineered for light transmission - yet their capacity as archival media remains untapped. This study explores a novel fiber Bragg grating (FBG) configuration exhibiting thermally programmable memory effects for optical data storage. Capitalizing on temperature-dependent spectral characteristics, we demonstrate finite spectral tuning through controlled thermal annealing, achieving irreversible spectral modifications via a light-induced stress mechanism analogous to the Kovacs memory effect in glassy materials. The engineered dual-dip FBG architecture enables multiplexed wavelength encoding, functioning simultaneously as a thermal history recorder and laser-writable data medium - mirroring the information knots of ancient quipu devices. This optical quipu concept pioneers one-dimensional photonic memory technology, opening new avenues for optical fiber applications in the information age. This work introduces a dual-dip fiber Bragg grating (FBG) with thermally programmable memory. Leveraging light-induced stress and thermal annealing, it enables irreversible spectral tuning—mimicking the Kovacs effect. The FBG serves as a laser-writable, multiplexed optical data storage medium and thermal history recorder.

Topics & Concepts

Fiber Bragg gratingMaterials scienceFiberPHOSFOSOptical fiberOptoelectronicsOpticsComposite materialFiber optic sensorPhysicsGraded-index fiberAdvanced Fiber Optic SensorsPhotonic and Optical DevicesPhotorefractive and Nonlinear Optics