Origin of optical losses in gallium arsenide disk whispering gallery resonators

Parrain, David; Baker, Christopher G.; Wang, Guillaume; Guha, Biswarup; Gil-Santos, Eduardo; Lemaı̂tre, A.; Senellart, P.; Leo, Giuseppe; Ducci, S.; Favero, Iván

doi:10.1364/oe.23.019656

Cited by 39 publications

(52 citation statements)

References 49 publications

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“…The loaded optical quality factor (Q opt ) evolves between 2 × 10 3 and 6 × 10 4 , with the best intrinsic Q opt attaining 10 5 . While a complete study of optical dissipation [17] was not yet carried on our InGaP disks, our current understanding is that such Q opt may be increased by improving the fabrication procedure, as the material loss sits well below the here-observed level [18]. The drop of Q factor observed in Fig.…”

Section: Optical and Mechanical Measurementsmentioning

confidence: 81%

“…The latter fact permits the production of heteroepitaxial materials with designed photon/phonon interactions, based for example on quantum wells [15]. Together with Si, GaAs is probably amongst the most mature materials in semiconductor technology but both suffer from two photon absorption (TPA) at the telecom wavelength [16,17]. At large optical power, such multi-photon absorption processes dominate optical dissipation and degrade the attainable cooperativity in the widely used linearized regime of optomechanics.…”

Section: Introductionmentioning

confidence: 99%

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High frequency optomechanical disk resonators in III–V ternary semiconductors

Guha¹,

Mariani²,

Lemaı̂tre³

et al. 2017

Opt. Express

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Optomechanical systems based on nanophotonics are advancing the field of precision motion measurement, quantum control and nanomechanical sensing. In this context III-V semiconductors offer original assets like the heteroepitaxial growth of optimized metamaterials for photon/phonon interactions. GaAs has already demonstrated high performances in optomechanics but suffers from two photon absorption (TPA) at the telecom wavelength, which can limit the cooperativity. Here, we investigate TPA-free III-V semiconductor materials for optomechanics applications: GaAs lattice-matched In0.5Ga0.5P and Al0.4Ga0.6As. We report on the fabrication and optical characterization of high frequency (500-700 MHz) optomechanical disks made out of these two materials, demonstrating high optical and mechanical Q in ambient conditions. Finally we achieve operating these new devices as laser-sustained optomechanical self-oscillators, and draw a first comparative study with existing GaAs systems.

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Section: Optical and Mechanical Measurementsmentioning

confidence: 81%

Section: Introductionmentioning

confidence: 99%

High frequency optomechanical disk resonators in III–V ternary semiconductors

Guha¹,

Mariani²,

Lemaı̂tre³

et al. 2017

Opt. Express

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View full text Add to dashboard Cite

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“…The obtained level of agreement sheds light on the microscopic nature of dissipation. The mechanical damping up to 100 K is well explained by an amorphous TLS model, which suggests a role of the surface reconstruction layer, whose amorphous nature was observed by transmission electron microscopy [39]. In order to model the dissipa-tion at higher T, the single defect model must however be used on top.…”

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confidence: 94%

Microscopic Nanomechanical Dissipation in Gallium Arsenide Resonators

et al. 2018

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We report on a systematic study of nanomechanical dissipation in high-frequency (≈300 MHz) gallium arsenide optomechanical disk resonators, in conditions where clamping and fluidic losses are negligible. Phonon-phonon interactions are shown to contribute with a loss background fading away at cryogenic temperatures (3 K). Atomic layer deposition of alumina at the surface modifies the quality factor of resonators, pointing towards the importance of surface dissipation. The temperature evolution is accurately fitted by two-level systems models, showing that nanomechanical dissipation in gallium arsenide resonators directly connects to their microscopic properties. Two-level systems, notably at surfaces, appear to rule the damping and fluctuations of such high-quality crystalline nanomechanical devices, at all temperatures from 3 to 300 K.

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“…Finally we briefly address the potential of micrometer-sized WGM resonators made of high refractive index semiconductors such as silicon [29,52] or gallium arsenide [5,53] for thin-film superfluid optomechanics. The optimal resonator thicknesses given in figure 2(d) are chosen to maximize the WGM deconfinement, resulting in low WGM effective indices, and therefore do not lend themselves to wavelength-sized radii without incurring significant bending losses [54]. For this reason we consider thicker more confining disks for this application, such as 200 nm thickness for TE modes [53].…”

Section: Miniaturized Third Sound Resonatorsmentioning

confidence: 99%

Theoretical framework for thin film superfluid optomechanics: towards the quantum regime

et al. 2016

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Excitations in superfluid helium represent attractive mechanical degrees of freedom for cavity optomechanics schemes. Here we numerically and analytically investigate the properties of optomechanical resonators formed by thin films of superfluid 4 He covering micrometer-scale whispering gallery mode cavities. We predict that through proper optimization of the interaction between film and optical field, large optomechanical coupling rates p >ǵ 2 100 kHz 0 and single photon cooperativities > C 10 0 are achievable. Our analytical model reveals the unconventional behaviour of these thin films, such as thicker and heavier films exhibiting smaller effective mass and larger zero point motion. The optomechanical system outlined here provides access to unusual regimes such as > W g M 0 and opens the prospect of laser cooling a liquid into its quantum ground state.

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Origin of optical losses in gallium arsenide disk whispering gallery resonators

Cited by 39 publications

References 49 publications

High frequency optomechanical disk resonators in III–V ternary semiconductors

High frequency optomechanical disk resonators in III–V ternary semiconductors

Microscopic Nanomechanical Dissipation in Gallium Arsenide Resonators

Theoretical framework for thin film superfluid optomechanics: towards the quantum regime

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