8,052 research outputs found
Width-tuned magnetic order oscillation on zigzag edges of honeycomb nanoribbons
Quantum confinement and interference often generate exotic properties in
nanostructures. One recent highlight is the experimental indication of a
magnetic phase transition in zigzag-edged graphene nanoribbons at the critical
ribbon width of about 7 nm [G. Z. Magda et al., Nature \textbf{514}, 608
(2014)]. Here we show theoretically that with further increase in the ribbon
width, the magnetic correlation of the two edges can exhibit an intriguing
oscillatory behavior between antiferromagnetic and ferromagnetic, driven by
acquiring the positive coherence between the two edges to lower the free
energy. The oscillation effect is readily tunable in applied magnetic fields.
These novel properties suggest new experimental manifestation of the edge
magnetic orders in graphene nanoribbons, and enhance the hopes of graphene-like
spintronic nanodevices functioning at room temperature.Comment: 22 pages, 9 figure
Moisture-triggered physically transient electronics
Physically transient electronics, a form of electronics that can physically disappear in a controllable manner, is very promising for emerging applications. Most of the transient processes reported so far only occur in aqueous solutions or biofluids, offering limited control over the triggering and degradation processes. We report novel moisture-triggered physically transient electronics, which exempt the needs of resorption solutions and can completely disappear within well-controlled time frames. The triggered transient process starts with the hydrolysis of the polyanhydride substrate in the presence of trace amounts of moisture in the air, a process that can generate products of corrosive organic acids to digest various inorganic electronic materials and components. Polyanhydride is the only example of polymer that undergoes surface erosion, a distinct feature that enables stable operation of the functional devices over a predefined time frame. Clear advantages of this novel triggered transience mode include that the lifetime of the devices can be precisely controlled by varying the moisture levels and changing the composition of the polymer substrate. The transience time scale can be tuned from days to weeks. Various transient devices, ranging from passive electronics (such as antenna, resistor, and capacitor) to active electronics ( such as transistor, diodes, optoelectronics, and memories), and an integrated system as a platform demonstration have been developed to illustrate the concept and verify the feasibility of this design strategy
Local Manifold Augmentation for Multiview Semantic Consistency
Multiview self-supervised representation learning roots in exploring semantic
consistency across data of complex intra-class variation. Such variation is not
directly accessible and therefore simulated by data augmentations. However,
commonly adopted augmentations are handcrafted and limited to simple
geometrical and color changes, which are unable to cover the abundant
intra-class variation. In this paper, we propose to extract the underlying data
variation from datasets and construct a novel augmentation operator, named
local manifold augmentation (LMA). LMA is achieved by training an
instance-conditioned generator to fit the distribution on the local manifold of
data and sampling multiview data using it. LMA shows the ability to create an
infinite number of data views, preserve semantics, and simulate complicated
variations in object pose, viewpoint, lighting condition, background etc.
Experiments show that with LMA integrated, self-supervised learning methods
such as MoCov2 and SimSiam gain consistent improvement on prevalent benchmarks
including CIFAR10, CIFAR100, STL10, ImageNet100, and ImageNet. Furthermore, LMA
leads to representations that obtain more significant invariance to the
viewpoint, object pose, and illumination changes and stronger robustness to
various real distribution shifts reflected by ImageNet-V2, ImageNet-R, ImageNet
Sketch etc
ILSGAN: Independent Layer Synthesis for Unsupervised Foreground-Background Segmentation
Unsupervised foreground-background segmentation aims at extracting salient
objects from cluttered backgrounds, where Generative Adversarial Network (GAN)
approaches, especially layered GANs, show great promise. However, without human
annotations, they are typically prone to produce foreground and background
layers with non-negligible semantic and visual confusion, dubbed "information
leakage", resulting in notable degeneration of the generated segmentation mask.
To alleviate this issue, we propose a simple-yet-effective explicit layer
independence modeling approach, termed Independent Layer Synthesis GAN
(ILSGAN), pursuing independent foreground-background layer generation by
encouraging their discrepancy. Specifically, it targets minimizing the mutual
information between visible and invisible regions of the foreground and
background to spur interlayer independence. Through in-depth theoretical and
experimental analyses, we justify that explicit layer independence modeling is
critical to suppressing information leakage and contributes to impressive
segmentation performance gains. Also, our ILSGAN achieves strong
state-of-the-art generation quality and segmentation performance on complex
real-world data.Comment: Accepted by AAAI 202
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