Zeroth-order half-wave plates of LiNbO₃ for integrated optics applications at 1.55 μm

“…Implantation-induced layer transfer processes have previously been reported for the layer transfer of Si, InP, Ge, and diamond. [4,5] Recently, layer splitting and transfer of ferroelectric materials such as LiNbO 3 , LiTaO 3 , KTaO 3 , SrTiO 3 , and BaTiO 3 have also been demonstrated through a sacrificial wet etching and anodic bonding process combined with a crystal ion slicing method. [6][7][8][9][10][11] However, because of large mismatch in the coefficient of thermal expansion (CTE) between LiNbO 3 ((7.5-14.4) × 10 -6 m°C -1 , depending on cutting orientation) and Si (2.6 × 10 -6 m°C -1…”

“…LiNbO 3 optical waveguides are of great importance in electro-optic applications [2,3] and could be substantially improved through a successful thin-film integration technology. Direct wafer bonding and layer-transfer techniques are promising methods for fabricating high-quality single-crystal thin films without heteroepitaxial growth and the attendant materials-defect problems associated with lattice mismatch between the thin-film layer and the silicon substrate.…”

Integration of Single‐Crystal LiNbO₃ Thin Film on Silicon by Laser Irradiation and Ion Implantation– Induced Layer Transfer

“…Implantation-induced layer transfer processes have previously been reported for the layer transfer of Si, InP, Ge, and diamond. [4,5] Recently, layer splitting and transfer of ferroelectric materials such as LiNbO 3 , LiTaO 3 , KTaO 3 , SrTiO 3 , and BaTiO 3 have also been demonstrated through a sacrificial wet etching and anodic bonding process combined with a crystal ion slicing method. [6][7][8][9][10][11] However, because of large mismatch in the coefficient of thermal expansion (CTE) between LiNbO 3 ((7.5-14.4) × 10 -6 m°C -1 , depending on cutting orientation) and Si (2.6 × 10 -6 m°C -1…”

“…LiNbO 3 optical waveguides are of great importance in electro-optic applications [2,3] and could be substantially improved through a successful thin-film integration technology. Direct wafer bonding and layer-transfer techniques are promising methods for fabricating high-quality single-crystal thin films without heteroepitaxial growth and the attendant materials-defect problems associated with lattice mismatch between the thin-film layer and the silicon substrate.…”

Integration of Single‐Crystal LiNbO₃ Thin Film on Silicon by Laser Irradiation and Ion Implantation– Induced Layer Transfer

“…The former include compact polarization-control building blocks for integrated optics circuits, 22,27 as well as low-noise pyroelectric optical detectors. 28 The latter are related to conventional LiNbO 3 devices transferred onto thin CIS films, namely passive optical circuits with annealed proton exchanged waveguides, 25 and also as active circuits in the form of thin-film optical modulators.…”

“…21,22 Thermal shock, in a form of a rapid temperature increase is applied to the implanted material, resulting in the lateral pressure release in the sacrificial (implanted) layer, and a subsequent separation of the CIS film from its parent wafer. The underlying physical mechanism for thermal lift-off is in fact similar to the wet-etch process described above.…”

“…The device had an extinction ratio >30dB at 1550 µm wavelength. 13 The most challenging task is the fabrication of thin-film Faraday rotators. The currently available 45°Faraday rotators have a thickness of typically about 0.5 mm and are therefore not suitable for the hybrid integration into planar lightwave circuits, simply because the diffraction loss that they would incur is too large.…”

Hybrid integrated tunable optical transmitter subsystem on a chip

Single-Crystal Lithium Niobate Films by Crystal Ion Slicing