Writing waveguides inside monolithic crystalline silicon with nanosecond laser pulses

Chambonneau, Maxime; Li, Qingfeng; Chanal, Margaux; Sanner, N.; Grojo, David

doi:10.1364/ol.41.004875

Cited by 50 publications

(43 citation statements)

References 15 publications

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“…Using a technique based on the one we have demonstrated in Ref. [22], the possible creation of waveguides using nanosecond pulses have recently been reported [23]. However, no experimental evidence of actual guidance of light was provided, only that the scattered light followed a linear pattern.…”

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confidence: 99%

Femtosecond laser written waveguides deep inside silicon

et al. 2017

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Photonic devices that can guide, transfer, or modulate light are highly desired in electronics and integrated silicon (Si) photonics. Here, we demonstrate for the first time, to the best of our knowledge, the creation of optical waveguides deep inside Si using femtosecond pulses at a central wavelength of 1.5 μm. To this end, we use 350 fs long, 2 μJ pulses with a repetition rate of 250 kHz from an Er-doped fiber laser, which we focused inside Si to create permanent modifications of the crystal. The position of the beam is accurately controlled with pump-probe imaging during fabrication. Waveguides that were 5.5 mm in length and 20 μm in diameter were created by scanning the focal position along the beam propagation axis. The fabricated waveguides were characterized with a continuous-wave laser operating at 1.5 μm. The refractive index change inside the waveguide was measured with optical shadowgraphy, yielding a value of 6 × 10 −4 , and by direct light coupling and far-field imaging, yielding a value of 3.5 × 10 −4 . The formation mechanism of the modification is discussed.

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confidence: 99%

Femtosecond laser written waveguides deep inside silicon

et al. 2017

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“…For example, let us consider the case of laser inscribed waveguides in silicon, c:Si, for telecommunication wavelength, λ = 1550 nm. Current techniques allow for control of refractive index properties, ∆n = n core − n bulk ∈ [1, 6] × 10 −3 , as well as losses, [0.1, 3]dB/cm, with waveguide length of about a centimetre [22,23]. We use the commercial finite element software COMSOL to simulate a necklace of two identical passive PT -symmetric dimers realized by four waveguides, radius r = 2.230 µm, in the configuration shown in Fig.…”

Section: Dimer Output Replicationmentioning

confidence: 99%

Necklaces of PT-symmetric dimers

Stevens¹,

Ávila²,

Rodríguez-Lara³

2018

Photon. Res.

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We study light propagation through cyclic arrays, composed by copies of a given PT -symmetric dimer, using a group theoretical approach and finite element modeling. The theoretical mode-coupling analysis suggest the use of these devices as output port replicators where the dynamics are controlled by the impinging light field. This is confirmed to good agreement with finite element propagation in an experimentally feasible necklace of passive PT -symmetric dimers constructed from lossy and lossless waveguides. arXiv:1709.00498v1 [physics.optics] 1 Sep 2017Necklaces of PT -symmetric dimers

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“…The in-chip technology is an emerging field, where there is a significant interest to build a photonics toolbox for nearinfrared applications, including fabrication of spatial light control elements [17,[19][20][21]. Notably, the wafer surface is unaltered after laser writing, thus the fabrication of in-chip devices leaves room for further on-chip or in-chip devices, with significant potential for multilayered functionality and novel 3D architectures [17,20].…”

Section: Introductionmentioning

confidence: 99%

“…In addition, they are highly desirable for integrating microfluidic technologies with photonic devices [8,13,23]. However, in spite of their importance for integrated optics [19] and biophotonics applications, in-chip waveguides remain limited to devices that require ultrafast lasers [20,21], or are created with nanosecond pulses where beam propagation suffers from scattering losses as the beam propagates in the laser-modified area [19]. In fact, to the best of our knowledge, there is only one other manuscript reporting performance of an in-chip waveguide by measuring its loss coefficient [21].…”

Section: Introductionmentioning

confidence: 99%

“…In this paper, we demonstrate low-loss, depressed-index cladding in-chip waveguides fabricated with nanosecond pulses and characterize the waveguide behavior at the wavelength of 1.3 μm. In general, laser-written waveguides based on a refractive-index depression require a more complex 3D topology [17], compared to those based on an optical index increase [19,20]. However, the depressed-index type waveguides have an architectural advantage because the beam propagates in the unmodified core, which has well-known optical and material properties.…”

Section: Introductionmentioning

confidence: 99%

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Laser-written depressed-cladding waveguides deep inside bulk silicon

2019

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Laser-written waveguides created inside transparent materials are important components for integrated optics. Here, we demonstrate that subsurface modifications induced by nanosecond pulses can be used to fabricate tubular-shaped "in-chip" or buried waveguides inside silicon. We first demonstrate single-line modifications, which are characterized to yield a refractive index depression of ≈2 × 10 −4 compared to that of the unmodified crystal. Combining these in a circular geometry, we realized 2.9-mm-long, 30-μm core-diameter waveguides inside the wafer. The waveguides operate in a single-mode regime at a wavelength of 1300 nm. We use near-and far-field imaging to confirm waveguiding and for optical index characterization. The waveguide loss is estimated from scattering experiments as 2.2 dB/cm.

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Writing waveguides inside monolithic crystalline silicon with nanosecond laser pulses

Cited by 50 publications

References 15 publications

Femtosecond laser written waveguides deep inside silicon

Femtosecond laser written waveguides deep inside silicon

Necklaces of PT-symmetric dimers

Laser-written depressed-cladding waveguides deep inside bulk silicon

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