Electro–optically tunable microring resonators in lithium niobate

Guarino, Andrea; Poberaj, G.; Rezzonico, Daniele; Degl’Innocenti, Riccardo; Günter, Peter

doi:10.1038/nphoton.2007.93

Cited by 519 publications

(333 citation statements)

References 22 publications

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“…However, today's silicon photonics technology does not exploit the linear electro-optical (EO) properties available in oxides, which for decades fuelled the progress in telecommunication based on fibre optics to extremely high modulation speeds with well-established devices 14 . In recent work, micro-scale EO devices have been presented 15 . These devices were based on LNO (LiNbO 3 ), which can be integrated as high-quality films on Si only via complex and costly layer-bonding approaches 16 .…”

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confidence: 99%

A strong electro-optically active lead-free ferroelectric integrated on silicon

et al. 2013

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The development of silicon photonics could greatly benefit from the linear electro-optical properties, absent in bulk silicon, of ferroelectric oxides, as a novel way to seamlessly connect the electrical and optical domain. Of all oxides, barium titanate exhibits one of the largest linear electro-optical coefficients, which has however not yet been explored for thin films on silicon. Here we report on the electro-optical properties of thin barium titanate films epitaxially grown on silicon substrates. We extract a large effective Pockels coefficient of r eff ¼ 148 pm V À 1 , which is five times larger than in the current standard material for electrooptical devices, lithium niobate. We also reveal the tensor nature of the electro-optical properties, as necessary for properly designing future devices, and furthermore unambiguously demonstrate the presence of ferroelectricity. The integration of electro-optical active films on silicon could pave the way towards power-efficient, ultra-compact integrated devices, such as modulators, tuning elements and bistable switches.

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confidence: 99%

A strong electro-optically active lead-free ferroelectric integrated on silicon

et al. 2013

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“…Alternatively, crystal ion slicing has been successfully employed to obtain high-quality thin films of crystalline LiNbO 3 [162][163][164][165]. A combination of deep helium ion implantation, selective etching and epoxy-resin bonding has been applied to transfer 5-to-10-μm-thick LiNbO 3 layers to silicon substrates [162].…”

Section: Second-order Nonlinear Photonics On Siliconmentioning

confidence: 99%

“…In another report, the adhesive polymer BCB, was used instead for wafer bonding and demonstrate electrooptically tunable LiNbO 3 -on-LiNbO 3 microring resonators [165]. Polymers, like epoxy-resin [162] or BCB [165], may be simple and straightforward solutions for lab demonstrations, but, as mentioned before, they are generally not reliable for practical applications due to the weak nature of the formed bonds.…”

Section: Second-order Nonlinear Photonics On Siliconmentioning

confidence: 99%

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Emerging heterogeneous integrated photonic platforms on silicon

Fathpour

2015

Nanophotonics

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Silicon photonics has been established as a mature and promising technology for optoelectronic integrated circuits, mostly based on the silicon-on-insulator (SOI) waveguide platform. However, not all optical functionalities can be satisfactorily achieved merely based on silicon, in general, and on the SOI platform, in particular. Long-known shortcomings of silicon-based integrated photonics are optical absorption (in the telecommunication wavelengths) and feasibility of electrically-injected lasers (at least at room temperature). More recently, high two-photon and free-carrier absorptions required at high optical intensities for third-order optical nonlinear effects, inherent lack of second-order optical nonlinearity, low extinction ratio of modulators based on the freecarrier plasma effect, and the loss of the buried oxide layer of the SOI waveguides at mid-infrared wavelengths have been recognized as other shortcomings. Accordingly, several novel waveguide platforms have been developing to address these shortcomings of the SOI platform. Most of these emerging platforms are based on heterogeneous integration of other material systems on silicon substrates, and in some cases silicon is integrated on other substrates. Germanium and its binary alloys with silicon, III-V compound semiconductors, silicon nitride, tantalum pentoxide and other high-index dielectric or glass materials, as well as lithium niobate are some of the materials heterogeneously integrated on silicon substrates. The materials are typically integrated by a variety of epitaxial growth, bonding, ion implantation and slicing, etch back, spin-on-glass or other techniques. These wide range of efforts are reviewed here holistically to stress that there is no pure silicon or even group IV photonics per se. Rather, the future of the field of integrated photonics appears to be one of heterogenization, where a variety of different materials and waveguide platforms will be used for different purposes with the common feature of integrating them on a single substrate, most notably silicon.

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“…Most of them utilize an etching step that defines the ridge geometry and a separate waveguide fabrication step [4][5][6] such as the commonly used ionindiffusion or proton-exchange processes. Delineation of the ridge is achieved either via wet etching in an acid mixture containing hydrofluoric acid (HF) or through dry etching processes such as ion beam milling 7 or plasma etching 8 . Domain-selective acid-based wet etching has also been reported as an alternative approach for defining ridges in domain engineered LN 9 .…”

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Poling-inhibited ridge waveguides in lithium niobate crystals

Sones

Ganguly

Ying

et al. 2010

Applied Physics Letters

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Ultraviolet laser irradiation of a lithium niobate +z polar surface enables the production of ridge waveguides. Ultraviolet laser induced inhibition of poling is used to define an inverted domain pattern which transforms into a ridge structure by differential etching in Hydrofluoric acid. The laser irradiation step also induces a refractive index change that provides the vertical confinement within the ridge structure. Furthermore, it was observed that poling-inhibition results in a significant enhancement of the refractive index contrast between the bulk crystal and the ultraviolet irradiated tracks.Lithium niobate (LN) because of its distinctive combination of inherent physical properties; has always been recognised as an appropriate platform for implementation of integrated optical circuits 1 . One of the suggested approaches which is quite regularly implemented to further improve the efficiency and compactness of such integrated optical circuits based on components such as modulators and resonators, is the use of ridge waveguides instead of conventional diffused 2 or proton-exchanged 3 waveguides. Such ridge waveguide superstructures provide better lateral confinement of the optical mode due to the much higher index contrast as compared to their conventional counterparts. Several different methods have been investigated for the production of ridge waveguides in LN. Most of them utilize an etching step that defines the ridge geometry and a separate waveguide fabrication step 4-6 such as the commonly used ionindiffusion or proton-exchange processes. Delineation of the ridge is achieved either via wet etching in an acid mixture containing hydrofluoric acid (HF) or through dry etching processes such as ion beam milling 7 or plasma etching 8 . Domain-selective acid-based wet etching has also been reported as an alternative approach for defining ridges in domain engineered LN 9 . Interestingly, ridge waveguides have also been fabricated by mechanical dicing of planar MgO:LN bonded on to LN 10 . The mandatory step required to induce the vertical refractive index (RI) contrast either precedes or succeeds the wet or dry etching process. In all of these approaches, a clean-room based photolithographic step is incorporated to define the ridge on an already produced planar waveguide or to define the waveguide on a prestructured ridge. Any alternative process that reduces the complexity of fabrication would be extremely well-suited for the implementation of the dense compact photonic circuits envisaged for future optoelectronic integration technologies. In this contribution we report on such an alternative method for the fabrication of ridge waveguides in z-cut LN. The method utilizes a continuous wave (c.w.) UV laser direct writing procedure that provides both the definition of the ridge pattern and the production of the necessary RI contrast for vertical confinement in a single step. Direct writing (DW) of waveguides in congruent LN has been demonstrated using c.w. UV laser light with writing wavelengths within the ran...

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Electro–optically tunable microring resonators in lithium niobate

Cited by 519 publications

References 22 publications

A strong electro-optically active lead-free ferroelectric integrated on silicon

A strong electro-optically active lead-free ferroelectric integrated on silicon

Emerging heterogeneous integrated photonic platforms on silicon

Poling-inhibited ridge waveguides in lithium niobate crystals

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