Flexible Plasmonics Using Aluminum and Copper Epitaxial Films on Mica

Quynh, Le Thi; Cheng, Chang‐Wei; Raja, Soniya S.; Mishra, Ragini; Yu, Meng-Ju; Lu, Yu; Gwo, Shangjr

doi:10.1021/acsnano.1c11191

Cited by 10 publications

(6 citation statements)

References 71 publications

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“…Beyond the typical precious metals, such as Au, [115][116][117] Ag, [118] Pt, [119] Ir, [120] and Pd, [121] there also exist several non-precious metals manifesting pronounced plasmonic effects, including Al, [122,123] Cu, [124][125][126] In, [127] Mo, [128] Sn, [129] Mg, [130] Sb, [131] Cu-Ni alloy, [132] Ga-In alloy, [133] etc. With the advantage of much lower cost, these materials have provided promising alternatives for the optical engineering research of next-generation optoelectronic devices.…”

Section: Non-noble Metal Optical Antenna Promoted 2dlm Photodetectorsmentioning

confidence: 99%

Promoting 2D Material Photodetectors by Optical Antennas beyond Noble Metals

et al. 2023

Advanced Sensor Research

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The distinctive layered crystal structures and diverse properties of 2D layered materials (2DLMs) have established them as prospective building blocks for implementing next‐generation optoelectronics. One critical predicament in terms of light sensing is the weak absorption caused by the atomic‐scale thickness, as well as the limited effective wavelength range/low spectral selectivity constrained by the intrinsic band structures. Despite the fact that numerous noble metal antennas are harnessed for enhancing the light–matter coupling, they suffer from exorbitant cost and narrow resonant optical windows. To this end, a number of non‐noble plasmonic optical antennas have been developed to improve the light‐sensing properties of 2DLM photodetectors, and tremendous advances have been accomplished. Herein, a comprehensive overview of this subject is provided based on four aspects; namely, non‐noble metal antenna promoted 2DLM photodetectors, heteroatom doped semiconductor antenna promoted 2DLM photodetectors, non‐stoichiometric semiconductor antenna promoted 2DLM photodetectors, and MXene antenna promoted 2DLM photodetectors. The focus is on the device structures, preparation, and underlying mechanisms. In the end, the challenges are highlighted, and potential strategies addressing them are proposed, which aim to navigate the upcoming exploration in the related domains and fully exert the pivotal role of non‐noble plasmonic optical antennas toward advancing 2DLM photodetectors.

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Section: Non-noble Metal Optical Antenna Promoted 2dlm Photodetectorsmentioning

confidence: 99%

Promoting 2D Material Photodetectors by Optical Antennas beyond Noble Metals

et al. 2023

Advanced Sensor Research

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“…In this scenario, bendable membranes will be the building block for applications such as strain sensors, wearable electronics, and photonics, flexible plasmonics, implantable robotic skin, etc. [2][3][4][5] A number of organic and inorganic materials have been mooted as candidates for flexible device integration, and 2D materials may play a key role in this respect as they offer robust mechanical properties, sustaining a high level of strain before fracturing, complemented by optical and electronic properties suitable for application in nano-photonics and -electronics. [6,7] Moreover, strain engineering has been shown to provide a great opportunity for 2D material-based functional applications taking advantage of mechanisms like electronic bandgap tuning, [8,9] exciton manipulation, [10,11] carrier mobility boosting [12][13][14] and piezoresistivity.…”

Section: Introductionmentioning

confidence: 99%

Bendable Silicene Membranes

et al. 2023

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Due to their superior mechanical properties, 2D materials have gained interest as active layers in flexible devices co‐integrating electronic, photonic, and straintronic functions altogether. To this end, 2D bendable membranes compatible with the technological process standards and endowed with large‐scale uniformity are highly desired. Here, it is reported on the realization of bendable membranes based on silicene layers (the 2D form of silicon) by means of a process in which the layers are fully detached from the native substrate and transferred onto arbitrary flexible substrates. The application of macroscopic mechanical deformations induces a strain‐responsive behavior in the Raman spectrum of silicene. It is also shown that the membranes under elastic tension relaxation are prone to form microscale wrinkles displaying a local generation of strain in the silicene layer consistent with that observed under macroscopic mechanical deformation. Optothermal Raman spectroscopy measurements reveal a curvature‐dependent heat dispersion in silicene wrinkles. Finally, as compelling evidence of the technological potential of the silicene membranes, it is demonstrated that they can be readily introduced into a lithographic process flow resulting in the definition of flexible device‐ready architectures, a piezoresistor, and thus paving the way to a viable advance in a fully silicon‐compatible technology framework.

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“…Therefore, deposition of ultrathin metal films typically requires additional wetting layers, resulting in increased optical losses and other device compatibility issues . Therefore, special growth techniques, such as growth at cryogenic temperatures , or on special substrates, are necessary to prepare ultrathin metal films without wetting layers. In this aspect, TiN offers an excellent opportunity for epitaxial growth of metals on semiconductor or oxide substrates because they have a mixture of covalent and metallic bonding …”

Section: Introductionmentioning

confidence: 99%

Ultrathin Titanium Nitride Epitaxial Structures for Tunable Infrared Plasmonics

Chang,

Huang,

et al. 2023

J. Phys. Chem. C

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Titanium nitride (TiN) is an ideal material for infrared plasmonics due to its excellent optical properties, high melting temperature, mechanical and chemical stabilities, and bioand CMOS compatibilities. In this work, we demonstrate that ultrathin and scalable TiN epitaxial structures can be applied for tunable infrared plasmonics, extending into near-to mid-infrared spectral regions. The ultrathin (111)-oriented TiN epitaxial films studied here were grown on c-plane sapphire wafers without any wetting layer by ultrahigh-vacuum nitrogen-plasma-assisted molecular-beam epitaxy. This method allows for stoichiometric TiN growth without the issue of contamination (especially oxygen) in conventional TiN growth techniques. Structural analyses for these films validate their single-crystalline properties with continuous film morphologies down to a few nanometers in thickness. Furthermore, the frequency-tunable (wavelength range: 1−4 μm) plasmonic metasurfaces have been demonstrated by controlling surface plasmon resonances via lithographically patterning of ultrathin TiN epitaxial films with varying thicknesses (4−30 nm) and grating structure parameters (pitch: 300−1200 nm, width: 200−800 nm). The tunable plasmonic metasurfaces based on ultrathin TiN epitaxial films hold great promise for emerging infrared plasmonic applications, such as thermal photovoltaics requiring narrow-band emitters, photodetectors, and biosensors in the near-and midinfrared spectral regions.

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Flexible Plasmonics Using Aluminum and Copper Epitaxial Films on Mica

Cited by 10 publications

References 71 publications

Promoting 2D Material Photodetectors by Optical Antennas beyond Noble Metals

Promoting 2D Material Photodetectors by Optical Antennas beyond Noble Metals

Bendable Silicene Membranes

Ultrathin Titanium Nitride Epitaxial Structures for Tunable Infrared Plasmonics

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