Mixed transition metal oxides (MTMOs) have received intensive attention as promising anode materials for lithium-ion batteries (LIBs) and sodium-ion batteries (SIBs). In this work, we demonstrate a facile one-step water-bath method for the preparation of graphene oxide (GO) decorated Fe2(MoO4)3 (FMO) microflower composite (FMO/GO), in which the FMO is constructed by numerous nanosheets. The resulting FMO/GO exhibits excellent electrochemical performances in both LIBs and SIBs. As the anode material for LIBs, the FMO/GO delivers a high capacity of 1,220 mAh·g–1 at 200 mA·g–1 after 50 cycles and a capacity of 685 mAh·g–1 at a high current density of 10 A·g–1. As the anode material for SIBs, the FMO/GO shows an initial discharge capacity of 571 mAh·g–1 at 100 mA·g–1, maintaining a discharge capacity of 307 mAh·g–1 after 100 cycles. The promising performance is attributed to the good electrical transport from the intimate contact between FMO and graphene oxide. This work indicates that the FMO/GO composite is a promising anode for high-performance lithium and sodium storage.
With the great potential of the all-polymer solar cells for large-area wearable devices, both large-area device efficiency and mechanical flexibility are very critical but attract limited attention. In this work, from the perspective of the polymer configurations, two types of terpolymer acceptors PYTX-A and PYTX-B (X = Cl or H) are developed. The configuration difference caused by the replacement of non-conjugated units results in distinct photovoltaic performance and mechanical flexibility. Benefiting from a good match between the intrinsically slow film-forming of the active materials and the technically slow film-forming of the blade-coating process, the toluene-processed large-area (1.21 cm2) binary device achieves a record efficiency of 14.70%. More importantly, a new parameter of efficiency stretchability factor (ESF) is proposed for the first time to comprehensively evaluate the overall device performance. PM6:PYTCl-A and PM6:PYTCl-B yield significantly higher ESF than PM6:PY-IT. Further blending with non-conjugated polymer donor PM6-A, the best ESF of 3.12% is achieved for PM6-A:PYTCl-A, which is among the highest comprehensive performances. 相似文献
This study describes techniques for the cascade modeling and the optimization that are required to conduct the simulator-based
process optimization of solar cell fabrication. Two modeling approaches, neural networks and genetic programming, are employed
to model the crucial relation for the consecutively connected two processes in solar cell fabrication. One model (Model 1)
is used to map the five inputs (time, amount of nitrogen and DI water in surface texturing and temperature and time in emitter
diffusion) to the two outputs (reflectance and sheet resistance) of the first process. The other model (Model 2) is used to
connect the two inputs (reflectance and sheet resistance) to the one output (efficiency) of the second process. After modeling
of the two processes, genetic algorithms and particle swarm optimization were applied to search for the optimal recipe. In
the first optimization stage, we searched for the optimal reflectance and sheet resistance that can provide the best efficiency
in the fabrication process. The optimized reflectance and sheet resistance found by the particle swarm optimization were better
than those found by the genetic algorithm. In the second optimization stage, the five input parameters were searched by using
the reflectance and sheet resistance values obtained in the first stage. The found five variables such as the texturing time,
amount of nitrogen, DI water, diffusion time, and temperature are used as a recipe for the solar cell fabrication. The amount
of nitrogen, DI water, and diffusion time in the optimized recipes showed considerable differences according to the modeling
approaches. More importantly, repeated applications of particle swarm optimization yielded process conditions with smaller
variations, implying greater consistency in recipe generation. 相似文献
With today’s global digital environment, the Internet is readily accessible anytime from everywhere, so does the digital image
manipulation software; thus, digital data is easy to be tampered without notice. Under this circumstance, integrity verification
has become an important issue in the digital world. The aim of this paper is to present an in-depth review and analysis on
the methods of detecting image tampering. We introduce the notion of content-based image authentication and the features required
to design an effective authentication scheme. We review major algorithms and frequently used security mechanisms found in
the open literature. We also analyze and discuss the performance trade-offs and related security issues among existing technologies. 相似文献
Surrogate models are used to dramatically improve the design efficiency of numerical aerodynamic shape optimization, where high-fidelity, expensive computational fluid dynamics (CFD) is often employed. Traditionally, in adaptation, only one single sample point is chosen to update the surrogate model during each updating cycle, after the initial surrogate model is built. To enable the selection of multiple new samples at each updating cycle, a few parallel infilling strategies have been developed in recent years, in order to reduce the optimization wall clock time. In this article, an alternative parallel infilling strategy for surrogate-based constrained optimization is presented and demonstrated by the aerodynamic shape optimization of transonic wings. Different from existing methods in which multiple sample points are chosen by a single infill criterion, this article uses a combination of multiple infill criteria, with each criterion choosing a different sample point. Constrained drag minimizations of the ONERA-M6 and DLR-F4 wings are exercised to demonstrate the proposed method, including low-dimensional (6 design variables) and higher-dimensional problems (up to 48 design variables). The results show that, for surrogate-based optimization of transonic wings, the proposed method is more effective than the existing parallel infilling strategies, when the number of initial sample points are in the range from Nv to 8Nv (Nv here denotes the number of design variables). Each case is repeated 50 times to eliminate the effect of randomness in our results. 相似文献
Impact of the discrete dopants on device performance is crucial in determining the behavior of nanoscale semiconductor devices. Atomistic quantum mechanical device simulation for studying the effect of discrete dopants on device's physical quantities is urgent. This work explores the physics of discrete-dopant-induced characteristic fluctuations in 16-nm fin-typed field effect transistor (FinFET) devices. Discrete dopants are statistically positioned in the three-dimensional channel region to examine associated carrier's characteristic, concurrently capturing “dopant concentration variation” and “dopant position fluctuation”. An experimentally validated quantum hydrodynamic device simulation was conducted to investigate the potential profile and threshold voltage fluctuations of the 16-nm FinFET. Results of this study provide further insight into the problem of fluctuation and the mechanism of immunity against fluctuation in 16-nm devices. 相似文献
