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In-chip critical plasma seeds for laser writing of reconfigurable silicon photonics systems

Andong Wang, Amlan Das, Vladimir Yu. Fedorov, Pol Sopeña, Stelios Tzortzakis, David Grojo

2025Nature Communications15 citationsDOIOpen Access PDF

Abstract

Ultrafast laser three-dimensional writing has made breakthroughs in manufacturing technologies. However, it remains rarely adopted for semiconductor technologies due to in-chip propagation nonlinearities causing a lack of controllability for intense infrared light. To solve this problem, plasma-optics concepts are promising since ultrashort laser pulses, even if inappropriate for direct writing, can readily inject high-density free-carriers inside semiconductors. To achieve highly localized and reliable processing, we create plasma seeds with tightly focused pre-ionizing femtosecond pulses. We show how critical density conditions can be used for extremely confined energy deposition with a synchronized writing irradiation and create ~ 1-µm-sized isotropic modifications inside silicon. Drastic improvement is also found on the material change controllability leading to unique demonstrations including rewritable optical memories (>100 writing/erasure cycles) and graded-index functionalities. By solving its controllability issues with critical plasma seeds, we show the potential of ultrafast laser writing for flexible fabrication of reconfigurable monolithic silicon-based optical devices.

Topics & Concepts

ControllabilityLaserFemtosecondUltrashort pulseOptoelectronicsMaterials sciencePhotonicsPlasmaSiliconSemiconductorChipComputer scienceOpticsNanotechnologyPhysicsTelecommunicationsApplied mathematicsQuantum mechanicsMathematicsLaser Material Processing TechniquesNonlinear Optical Materials StudiesAdvanced Fiber Laser Technologies
In-chip critical plasma seeds for laser writing of reconfigurable silicon photonics systems | Litcius