Electrically driven reprogrammable phase-change metasurface reaching 80% efficiency

Abdollahramezani, Sajjad; Hemmatyar, Omid; Taghinejad, Mohammad; Taghinejad, Hossein; Krasnok, Alex; Eftekhar, Ali A.; Teichrib, Christian; Deshmukh, Sanchit; El‐Sayed, Mostafa A.; Pop, Eric; Wuttig, Matthias; Alù, Andrea; Cai, Wenshan; Adibi, Ali

doi:10.1038/s41467-022-29374-6

Cited by 171 publications

(105 citation statements)

References 43 publications

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“…The structure demonstrated here provides the first truly wideband-tunable THG devices and paves the way for the design of nonlinear optical structures with improved efficiency and functionality for a wide range of applications, such as a combined band-and-phase modulation for THG microscopy. These structures can be combined with ultrafast and compact heating processes using indium tin oxide (ITO) Joule heaters, as demonstrated in other studies, [33][34][35] to form a new platform for electrically tunable chip-scale nonlinear optical devices. The structure here can also be a reliable platform for wideband tuning of THG with higher conversion efficiencies: 1) at the longer infrared wavelengths where the GST optical loss is minimal or 2) using alloys of GST, for example, Ge 2 Sb 2 Se 4 Te 1 (in short, GSST), [36,37] which provide less optical loss at the 1100-1600 nm wavelength range.…”

Section: Discussionmentioning

confidence: 99%

Broadband‐Tunable Third‐Harmonic Generation Using Phase‐Change Chalcogenides

Zhu

Abdollahramezani

et al. 2022

Advanced Photonics Research

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Despite remarkable progress in passive nonlinear nanophotonics, dynamically controlled ultracompact nonlinear optical sources with high efficiency remain elusive. Nonvolatility, large refractive index contrast between amorphous and crystalline phases, low thermal threshold for crystallization, and particularly high‐third‐order nonlinear optical susceptibility of phase‐change alloy Ge2Sb2Te5 (GST) make it a promising candidate for active subwavelength metaphotonic structures for realization of third‐harmonic generation (THG) devices. Herein, a GST‐based asymmetric Fabry–Perot cavity is numerically designed and experimentally demonstrated to show a dynamically reconfigurable structure with a large shift of the THG resonant band. In addition, continuous resonant spectral shifting bridged by a precisely controlled semicrystalline phase of GST is realized. Tunable THG with the fundamental wavelength ranging from 1150 to 1400 nm is presented, which corresponds to a broadband THG source in the violet‐blue visible wavelength range. Herein, the potential of GST subwavelength structures as a reliable platform for realization of the broadband‐tunable frequency‐conversion sources for applications such as THG microscopy and optical communication is indicated.

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Section: Discussionmentioning

confidence: 99%

Broadband‐Tunable Third‐Harmonic Generation Using Phase‐Change Chalcogenides

Zhu

Abdollahramezani

et al. 2022

Advanced Photonics Research

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“…If the temperature continues to rise, the regular crystals inside the cGST slowly turn into disordered nuclei again, and the cGST returns to aGST after undergoing rapid annealing at 640 • C (913.15 K) [57]. The whole reversible phase change process is continuously related to the heating temperature and heating time, and this process and the temperature profile for the reversible phase change operation can be described in various experimental ways [58][59][60][61]. For example, the electrical pulsing schemes and meta-atom temperature profiles are shown by designing an electrothermal metasurface switching [58], and the corresponding temperature responses can be obtained when the GST is heated by a resistive microheater integrated with a phase-change metasurface [59].…”

Section: Methodsmentioning

confidence: 99%

“…The whole reversible phase change process is continuously related to the heating temperature and heating time, and this process and the temperature profile for the reversible phase change operation can be described in various experimental ways [58][59][60][61]. For example, the electrical pulsing schemes and meta-atom temperature profiles are shown by designing an electrothermal metasurface switching [58], and the corresponding temperature responses can be obtained when the GST is heated by a resistive microheater integrated with a phase-change metasurface [59]. Since GST is non-volatile, once the phase transition is completed, it can maintain the corresponding state at room temperature for a long time, so our research was carried out at room temperature.…”

Section: Methodsmentioning

confidence: 99%

Tunable Infrared Detection, Radiative Cooling and Infrared-Laser Compatible Camouflage Based on a Multifunctional Nanostructure with Phase-Change Material

Luo

Zhang

et al. 2022

Nanomaterials

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The nanostructure composed of nanomaterials and subwavelength units offers flexible design freedom and outstanding advantages over conventional devices. In this paper, a multifunctional nanostructure with phase-change material (PCM) is proposed to achieve tunable infrared detection, radiation cooling and infrared (IR)-laser compatible camouflage. The structure is very simple and is modified from the classic metal–dielectric–metal (MIM) multilayer film structure. We innovatively composed the top layer of metals with slits, and introduced a non-volatile PCM Ge2Sb2Te5 (GST) for selective absorption/radiation regulation. According to the simulation results, wide-angle and polarization-insensitive dual-band infrared detection is realized in the four-layer structure. The transformation from infrared detection to infrared stealth is realized in the five-layer structure, and laser stealth is realized in the atmospheric window by electromagnetic absorption. Moreover, better radiation cooling is realized in the non-atmospheric window. The proposed device can achieve more than a 50% laser absorption rate at 10.6 μm while ensuring an average infrared emissivity below 20%. Compared with previous works, our proposed multifunctional nanostructures can realize multiple applications with a compact structure only by changing the temperature. Such ultra-thin, integratable and multifunctional nanostructures have great application prospects extending to various fields such as electromagnetic shielding, optical communication and sensing.

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“…Active tuning of amplitude, phase or polarization is achieved either by modifying the optical properties of these meta-atoms or those of their surroundings 23 , 24 . Recent studies have demonstrated the use of phase change materials 25 – 31 , transparent conducting oxides 9 , 32 – 34 , two-dimensional materials 35 – 39 , semiconductors 40 – 42 and liquid crystals 10 , 43 – 47 as tuning media, with very few examples achieving individual pixel control 9 , 10 , 34 . Moreover, using the concept of Huygens’ metasurfaces, it is possible to limit the coupling between amplitude and phase modulation 10 , 48 , 49 .…”

Section: Introductionmentioning

confidence: 99%

High resolution multispectral spatial light modulators based on tunable Fabry-Perot nanocavities

Mansha

Moitra

et al. 2022

Light Sci Appl

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Spatial light modulators (SLMs) are the most relevant technology for dynamic wavefront manipulation. They find diverse applications ranging from novel displays to optical and quantum communications. Among commercial SLMs for phase modulation, Liquid Crystal on Silicon (LCoS) offers the smallest pixel size and, thus, the most precise phase mapping and largest field of view (FOV). Further pixel miniaturization, however, is not possible in these devices due to inter-pixel cross-talks, which follow from the high driving voltages needed to modulate the thick liquid crystal (LC) cells that are necessary for full phase control. Newly introduced metasurface-based SLMs provide means for pixel miniaturization by modulating the phase via resonance tuning. These devices, however, are intrinsically monochromatic, limiting their use in applications requiring multi-wavelength operation. Here, we introduce a novel design allowing small pixel and multi-spectral operation. Based on LC-tunable Fabry-Perot nanocavities engineered to support multiple resonances across the visible range (including red, green and blue wavelengths), our design provides continuous 2π phase modulation with high reflectance at each of the operating wavelengths. Experimentally, we realize a device with 96 pixels (~1 μm pitch) that can be individually addressed by electrical biases. Using it, we first demonstrate multi-spectral programmable beam steering with FOV~18° and absolute efficiencies exceeding 40%. Then, we reprogram the device to achieve multi-spectral lensing with tunable focal distance and efficiencies ~27%. Our design paves the way towards a new class of SLM for future applications in displays, optical computing and beyond.

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Electrically driven reprogrammable phase-change metasurface reaching 80% efficiency

Cited by 171 publications

References 43 publications

Broadband‐Tunable Third‐Harmonic Generation Using Phase‐Change Chalcogenides

Broadband‐Tunable Third‐Harmonic Generation Using Phase‐Change Chalcogenides

Tunable Infrared Detection, Radiative Cooling and Infrared-Laser Compatible Camouflage Based on a Multifunctional Nanostructure with Phase-Change Material

High resolution multispectral spatial light modulators based on tunable Fabry-Perot nanocavities

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