Library of single-etch silicon nitride grating couplers for low-loss and fabrication-robust fiber-chip interconnection

Korček, Radovan; Medina Quiroz, David; Wilmart, Quentin; Edmond, Samson; Cheben, Pavel; Vivien, Laurent; Alonso-Ramos, Carlos; Benedikovič, Daniel

doi:10.1038/s41598-023-44824-x

Cited by 6 publications

(6 citation statements)

References 49 publications

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“…The calculated 1 dB and 3 dB bandwidths are 30 nm and 50 nm, respectively. These findings mark a significant improvement over the performance achievable with SiN-only couplers [27]. Furthermore, the efficiency can be further enhanced by increasing the fiber-grating overlap through coupler apodization, as discussed in the following section.…”

Section: (C)mentioning

confidence: 73%

“…To date, SOI and Si 3 N 4 photonic integrated circuits are now capable of achieving close to 1 dB efficiency through careful optimization of the directionality and field overlap between the radiated beam and the optical fiber mode. The fiber-grating field overlap, typically limited to 80% for uniform structures [24], can be enhanced through near-field apodization [25][26][27] or the beam-focalizing technique [28,29]. Near-field apodization is generally implemented by varying the geometry of the grating coupler in order to control the coupling length, i.e., to regulate the amount of waveguide power that is radiated by each grating period.…”

Section: Introductionmentioning

confidence: 99%

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High-Efficiency Metamaterial-Engineered Grating Couplers for Silicon Nitride Photonics

Fraser,

Korček,

Glesk

et al. 2024

Nanomaterials

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Silicon nitride (Si3N4) is an ideal candidate for the development of low-loss photonic integrated circuits. However, efficient light coupling between standard optical fibers and Si3N4 chips remains a significant challenge. For vertical grating couplers, the lower index contrast yields a weak grating strength, which translates to long diffractive structures, limiting the coupling performance. In response to the rise of hybrid photonic platforms, the adoption of multi-layer grating arrangements has emerged as a promising strategy to enhance the performance of Si3N4 couplers. In this work, we present the design of high-efficiency surface grating couplers for the Si3N4 platform with an amorphous silicon (α-Si) overlay. The surface grating, fully formed in an α-Si waveguide layer, utilizes subwavelength grating (SWG)-engineered metamaterials, enabling simple realization through single-step patterning. This not only provides an extra degree of freedom for controlling the fiber–chip coupling but also facilitates portability to existing foundry fabrication processes. Using rigorous three-dimensional (3D) finite-difference time-domain (FDTD) simulations, a metamaterial-engineered grating coupler is designed with a coupling efficiency of −1.7 dB at an operating wavelength of 1.31 µm, with a 1 dB bandwidth of 31 nm. Our proposed design presents a novel approach to developing high-efficiency fiber–chip interfaces for the silicon nitride integration platform for a wide range of applications, including datacom and quantum photonics.

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Section: (C)mentioning

confidence: 73%

Section: Introductionmentioning

confidence: 99%

High-Efficiency Metamaterial-Engineered Grating Couplers for Silicon Nitride Photonics

Fraser,

Korček,

Glesk

et al. 2024

Nanomaterials

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“…One solution to mitigate coupling losses and enhance tolerance is the implementation of vertical coupling grating structures in combination with waveguide tapers [9]. Grating couplers are described by the Bragg condition, as expressed in Equation (1), where N is an integer representing the diffraction order, λ0 is the free-space wavelength, neff is the effective refractive index of the grating, Λ is the grating period, and θ denotes the angle of light diffraction [18]. The light emitted by the grating exhibits an exponentially decaying power profile along the propagation direction [19].…”

Section: Photonic Biosensors With Highly Tolerant Grating Couplersmentioning

confidence: 99%

Repeatable Passive Fiber Optic Coupling of Single-Mode Waveguides in High-Precision Disposable Photonic Biosensors

Reck,

von Emden,

Mihov

et al. 2024

Photonics

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This research demonstrates a method for the repeatable passive fiber optic coupling of single-mode waveguides with a micron-scale accuracy for high-precision disposables. The aim is to broaden the application of photonic integrated circuits (PICs) from traditional fiber optic communication systems to include medical, life science, and environmental sensing applications. The proposed passive coupling system enables the straightforward and reliable interchange of disposable photonic chips without manual read-out unit adjustments. Robustness is attributed to the chip-side grating couplers with 3 dB coupling tolerances exceeding ± 25 µm and a mechanical three-groove kinematic method ensuring precise alignment. The system simplicity is highlighted by the simple manual insertion and fixation of silicon nitride (Si3N4) PICs on a carrier using magnetic force and passive alignment features. Testing on a batch of 99 identical yet independent units revealed a standard deviation (SD) of 5.1 dB in coupling loss, without realignment post-calibration. This eliminates the need for active alignment processes, showing its potential for enabling field use. A usability assessment with five untrained operators confirms the suitability for various end-users, with consistent performance in engaging and disengaging disposable PICs. The research significantly advances the integration of photonic sensor technology into practical applications, particularly for chemical and biological fluid analysis in point-of-care settings.

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“…The Si3N4 takes advantages of a broadband transparency, well-established deposition techniques, and a lower index contrast. So far, a wide range of chip-integrated building blocks has been developed and demonstrated, including ultra-low-loss and dispersion-engineered waveguides [4,5], splitters [6], resonators [7], filters [8], modulators [9] and fiber-chip grating and edge couplers [10][11][12][13], to name a few. The index contrast between the Si3N4 core and the claddings is low, therefore it is still an important design objective to realize efficient connections between the outside world and Si3N4 chips.…”

Section: Introductionmentioning

confidence: 99%

High-efficiency off-chip grating couplers for silicon nitride photonics

Korcek,

Fraser,

Wilmart

et al. 2024

Integrated Optics: Devices, Materials, and Technologies XXVIII

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Silicon nitride (Si3N4) is a leading platform in integrated photonics, providing unique passive functionalities, while maintaining compatibility with complementary metal-oxide-semiconductor processes and scalable and low-cost highvolume production. However, the moderate index contrast of the Si3N4 platform makes it difficult to implement efficient vertical surface grating couplers. In this work, we present efficient and robust fiber-chip grating couplers on native and hybrid Si3N4 platforms. Minimum coupling losses between -5 dB and -3 dB were measured for single-etch fabricated devices near 1.55 μm wavelength. Moreover, by leveraging the amorphous-silicon overlay on top of the Si3N4 platform, we develop hybrid single-etch grating couplers, with a coupling loss approaching 1 dB. The demonstrated grating couplers are promising for SiN integrated photonics, enabling a rapid and cost-effective chip interfacing with standard optical fibers. This opens up novel opportunities for rising applications, including optical communications, nonlinear optics, or quantum information sciences.

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Library of single-etch silicon nitride grating couplers for low-loss and fabrication-robust fiber-chip interconnection

Cited by 6 publications

References 49 publications

High-Efficiency Metamaterial-Engineered Grating Couplers for Silicon Nitride Photonics

High-Efficiency Metamaterial-Engineered Grating Couplers for Silicon Nitride Photonics

Repeatable Passive Fiber Optic Coupling of Single-Mode Waveguides in High-Precision Disposable Photonic Biosensors

High-efficiency off-chip grating couplers for silicon nitride photonics

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