A Deep Learning Approach for Objective-Driven All-Dielectric Metasurface Design

An, Sensong; Fowler, Clayton; Zheng, Bowen; Shalaginov, Mikhail Y.; Tang, Hong; Li, Hang; Zhou, Li; Ding, Jun; Agarwal, Anuradha M.; Rivero‐Baleine, Clara; Richardson, Kathleen; Gu, Tian; Hu, Juejun; Zhang, Hualiang

doi:10.1021/acsphotonics.9b00966

Cited by 252 publications

(183 citation statements)

References 43 publications

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“…[39] and assume that any intermediate value between the crystalline and the amorphous states can be reached. [45] To optimize the meta-atom geometry, we utilized a deep neural network design framework demonstrated in Ref [79] . The neural network was set to ensure close-to-2π phase coverage and to maintain high transmittance for GSST meta-atoms constrained to a maximum thickness of 400 nm.…”

Section: Nonvolatile Reconfigurable Transmissive Metasurfacesmentioning

confidence: 99%

Reversible Switching of Optical Phase Change Materials Using Graphene Microheaters

Rı́os¹,

Zhang²,

Deckoff-Jones³

et al. 2019

Conference on Lasers and Electro-Optics

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Reconfigurable photonic systems featuring minimal power consumption are crucial for integrated optical devices in real-world technology. Current active devices available in foundries, however, use volatile methods to modulate light, requiring a constant supply of power and significant form factors. Essential aspects to overcoming these issues are the development of nonvolatile optical reconfiguration techniques which are compatible with on-chip integration with different photonic platforms and do not disrupt their optical performances. In this paper, a solution is demonstrated using an optoelectronic framework for nonvolatile tunable photonics that employs undopedgraphene microheaters to thermally and reversibly switch the optical phase-change material Ge2Sb2Se4Te1 (GSST). An in-situ Raman spectroscopy method is utilized to demonstrate, in realtime, reversible switching between four different levels of crystallinity. Moreover, a 3D computational model is developed to precisely interpret the switching characteristics, and to quantify the impact of current saturation on power dissipation, thermal diffusion, and switching speed. This model is used to inform the design of nonvolatile active photonic devices; namely, broadband Si3N4 integrated photonic circuits with small form-factor modulators and reconfigurable metasurfaces displaying 2π phase coverage through neural-network-designed GSST meta-atoms. This framework will enable scalable, low-loss nonvolatile applications across a diverse range of photonics platforms.

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Section: Nonvolatile Reconfigurable Transmissive Metasurfacesmentioning

confidence: 99%

Reversible Switching of Optical Phase Change Materials Using Graphene Microheaters

Rı́os¹,

Zhang²,

Deckoff-Jones³

et al. 2019

Conference on Lasers and Electro-Optics

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“…In general, an active metasurface with j optical states (j ≥ 2) each characterized by m phase levels demands a minimum of m j distinct meta-atoms. The design problem, whose complexity escalates rapidly with increasing m and j, is best handled with deep learning based meta-atom design algorithms 63,64 and will be the subject of a follow-up paper.…”

Section: Discussionmentioning

confidence: 99%

Reconfigurable all-dielectric metalens with diffraction-limited performance

Shalaginov

Zhang

et al. 2020

Preprint

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Active metasurfaces, whose optical properties can be modulated post-fabrication, have emerged as an intensively explored field in recent years. The efforts to date, however, still face major performance limitations in tuning range, optical quality, and efficiency especially for non mechanical actuation mechanisms. In this paper, we introduce an active metasurface platform combining phase tuning covering the full 2π range and diffraction-limited performance using an all-dielectric, low-loss architecture based on optical phase change materials (O-PCMs). We present a generic design principle enabling binary switching of metasurfaces between arbitrary phase profiles and propose a new figure-of-merit tailored for active meta-optics. We implement the approach to realize a high-performance varifocal metalens operating at 5.2 μm wavelength. The metalens is constructed using Ge2Sb2Se4Te1 (GSST), an O-PCM with a large refractive index contrast (Δn > 1) and unique broadband low-loss characteristics in both amorphous and crystalline states. The reconfigurable metalens features focusing efficiencies above 20% at both states for linearly polarized light and a record large switching contrast ratio of 29.5 dB. We further validate aberration-free and multi-depth imaging using the metalens, which represents the first experimental demonstration of a non-mechanical active metalens with diffraction-limited performance.

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“…Therefore, this method enables efficient nanophotonic device evaluation and its design prediction. Overall, ML-assisted design approaches have already shown promising progress in developing a variety of high-performance metasurfaces [310,[314][315][316][317][318].…”

Section: Advanced Design and Optimization: Toward Multifunctional Metmentioning

confidence: 99%

“…When applied to active elements, the ML-assisted approaches were demonstrated to generate efficient designs of multifunctional and reconfigurable metadevices [316,323,325]. Encountered by the dramatically enlarged DOFs and associated uncertainties, design constraining rules, which take into account experimental imperfections, have been incorporated in several design frameworks to enhance their robustness [316,317,320]. In Section 7, we illustrate the use of ML methods to blueprint multifunctional active metadevice designs based on O-PCMs.…”

Section: Advanced Design and Optimization: Toward Multifunctional Metmentioning

confidence: 99%

“…While the MOO techniques enable the exploration of significantly expanded design spaces, it is also highly desirable to develop design generation and validation tools in place of full-wave electromagnetic modeling to complement the optimization algorithms and enhance the design throughput. A recently emerged DNN-based metasurface design and characterization approach [316,323,328] offers a promising solution to address the design throughput challenge. In the study by An et al [316], an all-dielectric reconfigurable meta-atom design based on NNs was presented.…”

Section: Multifunctional Meta-atoms Design Using Deep Neural Networkmentioning

confidence: 99%

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Design for quality: reconfigurable flat optics based on active metasurfaces

Shalaginov

Campbell

et al. 2020

Nanophotonics

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Optical metasurfaces, planar subwavelength nanoantenna arrays with the singular ability to sculpt wavefront in almost arbitrary manners, are poised to become a powerful tool enabling compact and high-performance optics with novel functionalities. A particularly intriguing research direction within this field is active metasurfaces, whose optical response can be dynamically tuned postfabrication, thus allowing a plurality of applications unattainable with traditional bulk optics. Designing reconfigurable optics based on active metasurfaces is, however, presented with a unique challenge, since the optical quality of the devices must be optimized at multiple optical states. In this article, we provide a critical review on the active meta-optics design principles and algorithms that are applied across structural hierarchies ranging from single meta-atoms to full meta-optical devices. The discussed approaches are illustrated by specific examples of reconfigurable metasurfaces based on optical phase-change materials.

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A Deep Learning Approach for Objective-Driven All-Dielectric Metasurface Design

Cited by 252 publications

References 43 publications

Reversible Switching of Optical Phase Change Materials Using Graphene Microheaters

Reversible Switching of Optical Phase Change Materials Using Graphene Microheaters

Reconfigurable all-dielectric metalens with diffraction-limited performance

Design for quality: reconfigurable flat optics based on active metasurfaces

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