Compact Brillouin devices through hybrid integration on silicon

Morrison, Blair; Casas-Bedoya, Alvaro; Ren, Guanghui; Vu, Khu; Liu, Yang; Zarifi, Atiyeh; Nguyen, Thach G.; Choi, Duk‐Yong; Marpaung, David; Madden, Steve; Mitchell, Arnan; Eggleton, Benjamin J.

doi:10.1364/optica.4.000847

Cited by 152 publications

(104 citation statements)

References 50 publications

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“…At the transparency condition C = 1 the phonon noise goes down, eventually reaching the mechanical Schawlow-Townes limit. Several such "phonon lasers" have been demonstrated already, relying on very different integration platforms [150,156,[261][262][263]. Further work is needed to determine if these devices can deliver the performance required to compete with existing microwave oscillators.…”

Section: Microwave Signal Processingmentioning

confidence: 99%

Controlling phonons and photons at the wavelength scale: integrated photonics meets integrated phononics

Safavi-Naeini

Thourhout

Baets

et al. 2019

Optica

163

167

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Radio-frequency communication systems have long used bulk-and surface-acoustic-wave devices supporting ultrasonic mechanical waves to manipulate and sense signals. These devices have greatly improved our ability to process microwaves by interfacing them to orders-ofmagnitude slower and lower loss mechanical fields. In parallel, long-distance communications have been dominated by low-loss infrared optical photons. As electrical signal processing and transmission approaches physical limits imposed by energy dissipation, optical links are now being actively considered for mobile and cloud technologies. Thus there is a strong driver for wavelength-scale mechanical wave or "phononic" circuitry fabricated by scalable semiconductor processes. With the advent of these circuits, new micro-and nanostructures that combine electrical, optical and mechanical elements have emerged. In these devices, such as optomechanical waveguides and resonators, optical photons and gigahertz phonons are ideally matched to one another as both have wavelengths on the order of micrometers. The development of phononic circuits has thus emerged as a vibrant field of research pursued for optical signal processing and sensing applications as well as emerging quantum technologies. In this review, we discuss the key physics and figures of merit underpinning this field. We also summarize the state of the art in nanoscale electro-and optomechanical systems with a focus on scalable platforms such as silicon. Finally, we give perspectives on what these new systems may bring and what challenges they face in the coming years. In particular, we believe hybrid electro-and optomechanical devices incorporating highly coherent and compact mechanical elements on a chip have significant untapped potential for electro-optic modulation, quantum microwave-tooptical photon conversion, sensing and microwave signal processing.

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Section: Microwave Signal Processingmentioning

confidence: 99%

Controlling phonons and photons at the wavelength scale: integrated photonics meets integrated phononics

Safavi-Naeini

Thourhout

Baets

et al. 2019

Optica

163

167

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show abstract

“…Compared to Si or Ge, the drawback of this approach is that chalcogenides and halides are generally not considered compatible with CMOS foundry processes. However, the recent report of chalcogenide device integration with silicon waveguides indicates that such a hybrid configuration can enable seamless integration of unconventional materials with the standard silicon photonics platform [39]. Table 1 shows the available passive platforms for mid-IR integrated photonics on Si, including the best reported results on low loss performance obtained in each category.…”

Section: Waveguides and Passive Devicesmentioning

confidence: 99%

Mid-infrared integrated photonics on silicon: a perspective

et al. 2017

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Abstract:The emergence of silicon photonics over the past two decades has established silicon as a preferred substrate platform for photonic integration. While most silicon-based photonic components have so far been realized in the near-infrared (near-IR) telecommunication bands, the mid-infrared (mid-IR, 2-20-μm wavelength) band presents a significant growth opportunity for integrated photonics. In this review, we offer our perspective on the burgeoning field of mid-IR integrated photonics on silicon. A comprehensive survey on the state-of-the-art of key photonic devices such as waveguides, light sources, modulators, and detectors is presented. Furthermore, on-chip spectroscopic chemical sensing is quantitatively analyzed as an example of mid-IR photonic system integration based on these basic building blocks, and the constituent component choices are discussed and contrasted in the context of system performance and integration technologies.

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“…(c) SBS interaction between the acoustic mode identified as corresponding to the maximum of Q m in (a) as A and the HE 17 optical mode. The three panels represent the displacement field separated into S and P components, the axial Poynting vector P z of the optical mode, and the dominant, real part of the overlap functionQ (PE) 1 (r) originating from the PE interaction defined in (13). (d) SBS gain between the acoustic mode marked as A in (a) and the phase-matched HE modes of decreasing order (and increasing effective optical mode index) HE 17 through HE 12 . and the Pockels tensor (p ijkl ).…”

Section: Stimulated Brillouin Scattering In Cylindrical Arrawsmentioning

confidence: 99%

“…In others, both light and sound are guided along line defects of phoxonic crystals [9][10][11]. Finally, a combination of the desired material properties-high refractive index and low stiffness-has been identified in chalcogenides, allowing researchers to revisit step-index architectures for optoacoustic waveguides [12,13].…”

Section: Introductionmentioning

confidence: 99%

ARRAW: anti-resonant reflecting acoustic waveguides

Schmidt¹,

O'Brien²,

Steel³

et al. 2020

New J. Phys.

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Development of acoustic and optoacoustic on-chip technologies calls for new solutions to guiding, storing and interfacing acoustic and optical waves in integrated silicon-on-insulator systems. One of the biggest challenges in this field is to suppress the radiative dissipation of the propagating acoustic waves, while co-localizing the optical and acoustic fields in the same region of an integrated waveguide. Here we address this problem by introducing anti-resonant reflecting acoustic waveguides (ARRAWs)—mechanical analogues of the anti-resonant reflecting optical waveguides. We discuss the principles of anti-resonant guidance and establish guidelines for designing efficient ARRAWs. Finally, we demonstrate examples of the simplest silicon/silica ARRAW platforms that can simultaneously serve as near-IR optical waveguides, and support strong backward Brillouin scattering.

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Compact Brillouin devices through hybrid integration on silicon

Cited by 152 publications

References 50 publications

Controlling phonons and photons at the wavelength scale: integrated photonics meets integrated phononics

Controlling phonons and photons at the wavelength scale: integrated photonics meets integrated phononics

Mid-infrared integrated photonics on silicon: a perspective

ARRAW: anti-resonant reflecting acoustic waveguides

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