Formation of ferromagnetic Co–H–Co complex and spin-polarized conduction band in Co-doped ZnO

Lee, Seunghun; Park, Ji Hun; Kim, Bum-Su; Cho, Deok‐Yong; Choi, Yong Nam; Lee, Tae‐Woo; Kim, Wonkyung; Kim, Doukyun; Cho, Chae Ryong; Moriyoshi, Chikako; Park, Chul Hong; Kuroiwa, Yoshihiro; Jeong, Se–Young

doi:10.1038/s41598-017-11078-3

Cited by 15 publications

(20 citation statements)

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“…In particular, for Co-doped ZnO thin films it has been shown that a large enhancement in the ferromagnetic behavior can be induced by a suitable atomic hydrogen treatment, without the formation of metal Co nanophases. [8][9][10][11] In the context of DMS, the MO effect is useful to investigate the strength and the nature of the ferromagnetism as arising from spin polarized carriers magnetically coupled to magnetic ions. However, due to the presence of a finite optical absorption, the polarization of the transmitted light rotates and turns from linear (i.e.…”

Section: Introductionmentioning

confidence: 99%

Giant magneto-optical response in H⁺ irradiated Zn_1−xCo_xO thin films

et al. 2019

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Section: Introductionmentioning

confidence: 99%

Giant magneto-optical response in H⁺ irradiated Zn_1−xCo_xO thin films

et al. 2019

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“…These typically induce a larger strain due to bending at a larger angle, as shown in Figure d,e. However, the sensor responses were relatively slow upon release, which is probably attributed to the softness and viscoelastic behavior of the composite film . One may be able to improve the recovery time by further optimizing the materials used in the conductive composite.…”

Section: Resultsmentioning

confidence: 99%

Highly Sensitive and Stretchable Resistive Strain Sensors Based on Microstructured Metal Nanowire/Elastomer Composite Films

Kim

Jang

et al. 2018

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High sensitivity and high stretchability are two conflicting characteristics that are difficult to achieve simultaneously in elastic strain sensors. A highly sensitive and stretchable strain sensor comprising a microstructured metal nanowire (mNW)/elastomer composite film is presented. The surface structure is easily prepared by combining an mNW coating and soft-lithographic replication processes in a simple and reproducible manner. The densely packed microprism-array architecture of the composite film leads to a large morphological change in the mNW percolation network by efficiently concentrating the strain in the valley regions upon stretching. Meanwhile, the percolation network comprising mNWs with a high aspect ratio is stable enough to prevent electrical failure, even under high strains. This enables the sensor to simultaneously satisfy high sensitivity (gauge factor ≈81 at >130% strain) and high stretchability (150%) while ensuring long-term reliability (10 000 cycles at 150% strain). The sensor can also detect strain induced by bending and pressure, thus demonstrating its potential as a versatile sensing tool. The sensor is successfully utilized to monitor a wide range of human motions in real time. Furthermore, the unique sensing mechanism is easily extended to detect more complex multiaxial strains by optimizing the surface morphology of the device.

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“…For example, a mass of microstructures was utilized such as micropyramidal, microdome, microcavity, microcracks, thickness‐gradient structures, even metamaterial structure . Biomaterials, nanocomposites, triboelectric and piezoelectric materials, stimuli‐responsive polymers, hydrogels, and so on, were exploited to enhance the functionalities and to extend the limits owned by traditional silicon‐based materials . Aforementioned, multiple receptors are involved in the formation of tactile sensation, which has also inspired the design and integration of artificial sensors with versatile sensing capabilities …”

Section: Understanding Sensory Memorymentioning

confidence: 99%

Artificial Sensory Memory

et al. 2019

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The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/adma.201902434. Sensory memory, formed at the beginning while perceiving and interacting with the environment, is considered a primary source of intelligence. Transferring such biological concepts into electronic implementation aims at achieving perceptual intelligence, which would profoundly advance a broad spectrum of applications, such as prosthetics, robotics, and cyborg systems. Here, the recent developments in the design and fabrication of artificial sensory memory devices are summarized and their applications in recognition, manipulation, and learning are highlighted. The emergence of such devices benefits from recent progress in both bioinspired sensing and neuromorphic engineering technologies and derives from abundant inspiration and benchmarks from an improved understanding of biological sensory processing. Increasing attention to this area would offer unprecedented opportunities toward new hardware architecture of artificial intelligence, which could extend the capabilities of digital systems with emotional/psychological attributes. Pending challenges are also addressed to aspects such as integration level, energy efficiency, and functionality, which would undoubtedly shed light on the future development of translational implementations. Artificial Sensory Neurons

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Formation of ferromagnetic Co–H–Co complex and spin-polarized conduction band in Co-doped ZnO

Cited by 15 publications

References 74 publications

Giant magneto-optical response in H⁺ irradiated Zn_1−xCo_xO thin films

Giant magneto-optical response in H⁺ irradiated Zn_1−xCo_xO thin films

Highly Sensitive and Stretchable Resistive Strain Sensors Based on Microstructured Metal Nanowire/Elastomer Composite Films

Artificial Sensory Memory

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Formation of ferromagnetic Co–H–Co complex and spin-polarized conduction band in Co-doped ZnO

Cited by 15 publications

References 74 publications

Giant magneto-optical response in H+ irradiated Zn1−xCoxO thin films

Giant magneto-optical response in H+ irradiated Zn1−xCoxO thin films

Highly Sensitive and Stretchable Resistive Strain Sensors Based on Microstructured Metal Nanowire/Elastomer Composite Films

Artificial Sensory Memory

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Giant magneto-optical response in H⁺ irradiated Zn_1−xCo_xO thin films

Giant magneto-optical response in H⁺ irradiated Zn_1−xCo_xO thin films