Low-loss integrated photonics for the blue and ultraviolet regime

Abstract: We present a low-loss integrated photonics platform in the visible and near ultraviolet regime. Fully-etched waveguides based on atomic layer deposition (ALD) of aluminum oxide operate in a single transverse mode with <3 dB/cm propagation loss at a wavelength of 371 nm. Ring resonators with intrinsic quality factors exceeding 470,000 are demonstrated at 405 nm, and the thermo optic coefficient of ALD aluminum oxide is estimated to be 2.75 × 10 −5 [RIU/ • C]. Absorption loss is sufficiently low to allow on-reso… Show more

“…These same techniques could be applied to realize so-called analog quantum simulators in ion trap arrays [32][33][34], possibly with integrated control [35]. Moreover, such an approach may enable the embedding of complex integrated components such as trench capacitors [36,37], low-loss integrated waveguides [38]; or the realization of more elaborate devices including reliable iontransport junctions [39,40], increased optical access [17] or manipulation of scalable arrays of two-dimensional trapped ion systems [33,34].…”

Multilayer ion trap technology for scalable quantum computing and quantum simulation

“…These same techniques could be applied to realize so-called analog quantum simulators in ion trap arrays [32][33][34], possibly with integrated control [35]. Moreover, such an approach may enable the embedding of complex integrated components such as trench capacitors [36,37], low-loss integrated waveguides [38]; or the realization of more elaborate devices including reliable iontransport junctions [39,40], increased optical access [17] or manipulation of scalable arrays of two-dimensional trapped ion systems [33,34].…”

Multilayer ion trap technology for scalable quantum computing and quantum simulation

“…This may be due to the higher refractive index of the LPCVD SiN causing increased sidewall scattering. This may also be due to the absorption mechanism noted in [9] at wavelengths close to and below 400 nm. However, since the exact roughness of each wafer was not quantified, variations in roughness between the wafers may also contribute to this observation.…”

“…In [5] on 200 mm wafers, single-mode SiN waveguides formed by plasma enhanced chemical vapour deposition (PECVD) exhibited a loss of about 1 dB/cm at a wavelength of 532 nm. In [8,9], SiN waveguide losses ≤ 20.7 dB/cm and Al 2 O 3 waveguide losses ≤ 1.6 dB/cm were observed at 4 discrete wavelengths between 405 nm and 458 nm; losses as low as 4.8 and 0.6 dB/cm were observed at 458 nm for the SiN and Al 2 O 3 waveguides, respectively. Although SiN generally exhibited higher losses than Al 2 O 3 in that demonstration, the CMOS compatibility and fabrication maturity of SiN makes it a promising material for further development for visible light integrated photonics platforms.…”

“…To date, single-mode visible light waveguides have been demonstrated using SiN [5][6][7] and alumina (Al 2 O 3 ) [8,9] on 200 mm or 300 mm Si wafers, and using aluminum nitride (AlN) with chip-scale fabrication [10]. However, in all of these demonstrations, waveguide losses were only reported at discrete wavelengths, and complete, continuous waveguide loss spectra were not obtained.…”

Visible-light silicon nitride waveguide devices and implantable neurophotonic probes on thinned 200 mm silicon wafers

“…Aluminum oxide (Al 2 O 3 ) is an emerging photonic material that exhibits a large transparency window covering the visible and near-infrared wavelength ranges [14]. When doped with rare-Earth ions, it provides optical gain that has been used to demonstrate on-chip amplifiers [15] and lasers [16,17].…”

Al₂O₃:Yb³⁺ integrated microdisk laser label-free biosensor