Fig. 1 Microstructure of bulk UFG/nanocrystalline Cu-containing distributed WC nanoparticles. Microstructure of bulk UFG/nanocrystalline Cu-containing.

Slides:

Advertisements

Similar presentations

Fig. 4 3D reconfiguration of liquid metals for electronics.

Advertisements

Fig. 5 MicroLED array with 3D liquid metal interconnects.

Fig. 1 High-resolution printing of liquid metals.

Fig. 3 FM MnBi2Te4 bulk. FM MnBi2Te4 bulk. Crystal structure (A) and band structure (B) of the FM bulk. (C) Zoom-in band structures along the out-of-plane.

Fig. 3 The electrical contact of direct-printed and reconfigured liquid metals. The electrical contact of direct-printed and reconfigured liquid metals.

Fig. 2 Global production, use, and fate of polymer resins, synthetic fibers, and additives (1950 to 2015; in million metric tons). Global production, use,

Fig. 4 INS spectra of different human bones from the Roman period [humerus, ulna, femur, and fibula from the same skeleton, Guidonia-Montecelio, Italy.

Fig. 2 CFD results. CFD results. Results of CFD simulations in horizontal (left column) and vertical (right column) cross-sections. All models oriented.

Fig. 3 Vibrational spectra of human bones from the Copper Age (Scoglietto cave, Italy). Vibrational spectra of human bones from the Copper Age (Scoglietto.

Vibrational spectra of medieval human bones (Leopoli-Cencelle, Italy)

Fig. 1 Pump-probe signatures of vermilion (red HgS), black HgS, and metallic Hg. Pump-probe signatures of vermilion (red HgS), black HgS, and metallic.

Fig. 1 Map of water stress and shale plays.

Fig. 1 Examples of experimental stimuli and behavioral performance.

Fig. 1 Wireless, battery-free neural cuff for programmable pharmacology and optogenetics. Wireless, battery-free neural cuff for programmable pharmacology.

Fig. 4 Resynthesized complex boronic acid derivatives based on different scaffolds on a millimole scale and corresponding yields. Resynthesized complex.

HT synthesis of boronic acids using the building block approach

Fig. 6 Comparison of properties of water models.

Fig. 1 Mean and median RCR (Relative Citation Ratio) of Roadmap Epigenomics Program research articles for each year. Mean and median RCR (Relative Citation.

Fig. 2 Ferroelectric domains resolved in WTe2 single crystals.

Fig. 3 Swarm material properties.

Fig. 2 The glucose binding and charge-switch study.

Fig. 3 Glucose- and structure-dependent insulin release.

Fig. 3 Scan rate effects on the layer edge current.

Fig. 2 TRXSS data. TRXSS data. TRXSS data covering delay times from 10 ns to 10 ms for wild-type DmCry (A), for the DmCry(H378A) mutant (B), and for XlPho.

Fig. 3 Rotation experiment, setup.

Fig. 1 Product lifetime distributions for the eight industrial use sectors plotted as log-normal probability distribution functions (PDF). Product lifetime.

FTIR-ATR spectra of Neolithic faunal bones (Mora Cavorso cave, Italy)

Fig. 1 The structure of the 3DGraphene foam.

Fig. 1 Distribution of total and fake news shares.

Fig. 2 2D QWs of different propagation lengths.

Fig. 5 Chaetopterus tube lining formed in seawater or within sediment.

Fig. 4 EUV TG signal from Si.

Fig. 6 WPS imaging of different chemical components in living cells.

Fig. 3 Load dependence of friction force and corresponding COF.

Fig. 1 Sectional distributions of pigment concentrations measured along the Mediterranean Sea and in the Eastern Atlantic Ocean. Sectional distributions.

Fig. 3 ET dynamics on the control and treatment watersheds during the pretreatment and treatment periods. ET dynamics on the control and treatment watersheds.

Fig. 1 Histograms of the number of first messages received by men and women in each of our four cities. Histograms of the number of first messages received.

Fig. 5 Schematic phase diagrams of Ising spin systems and Mott transition systems. Schematic phase diagrams of Ising spin systems and Mott transition systems.

Characteristics of ultrathin single-crystalline semiconductor films

Fig. 1 X-ray scattering and EBSD analyses of the bulk Fe25Co25Ni25Al10Ti15 HEA. X-ray scattering and EBSD analyses of the bulk Fe25Co25Ni25Al10Ti15 HEA.

Fig. 1 Average contribution (million metric tons) of seafood-producing sectors, 2009–2014. Average contribution (million metric tons) of seafood-producing.

Fig. 4 Praying Prophet by Lorenzo Monaco: Mapping lake pigments and associated substrate. Praying Prophet by Lorenzo Monaco: Mapping lake pigments and.

Fig. 1 Cross-sectional images of He-implanted V/Cu/V samples.

Nanoparticle-enabled grain refinement in other materials systems

Fig. 4 Evolution of fraction of sickled RBCs under hypoxia.

Fig. 1 Structure and absorption spectra of the P

Fig. 1 Time course of growth parameters for acetate-grown cultures of M. acetivorans with and without supplements. Time course of growth parameters for.

Fig. 3 Production of protein and Fe(II) at the end of growth correlated with increasing concentrations of ferrihydrite in the media that contained 0.2.

Fig. 4 SPICE simulation of stochasticity.

Fig. 1 Size fractions of MPPs in different fertilizers.

Fig. 2 Sampling. Sampling. (A) Extant stratigraphic section. Zenithal (B) and frontal (C) views of the flowstone capping the excavated deposit. The rectangle.

Fig. 5 Comparison of the liquid products generated from photocatalytic CO2 reduction reactions (CO2RR) and CO reduction reactions (CORR) on two catalysts.

Fig. 3 Relationships between Q10 and C distribution in aggregates.

Fig. 2 Construction of a mimetic biomineralization frontier for epitaxial crystal growth by using CPICs. Construction of a mimetic biomineralization frontier.

Fig. 4 BS-SEM images, ternary diagrams, and phase maps for the text and reverse sides of the TS. BS-SEM images, ternary diagrams, and phase maps for the.

Fig. 1 Location of the Jirzankal Cemetery.

Fig. 4 CO2 emission changes triggered by the JJJ clean air policy.

Fig. 6 MSC encapsulation in vitro within PdBT cross-linked gels.

Fig. 1 Structural and electrical properties of Bi2Se3/BaFe12O19.

Fig. 4 Phase diagram showing significant order parameters ∣pk∣ versus T and wc. Phase diagram showing significant order parameters ∣pk∣ versus T and wc.

Fig. 3 Comparisons of NDVI trends over the globally vegetated areas from 1982 to Comparisons of NDVI trends over the globally vegetated areas from.

Fig. 4 Spatial mapping of the distribution and intensity of industrial fishing catch. Spatial mapping of the distribution and intensity of industrial fishing.

Fig. 3 Device architecture, photovoltaic performance, and operational stability of 3D/2D bilayer PSCs. Device architecture, photovoltaic performance, and.

Fig. 4 Single-particle contact angle measurements.

Fig. 6 MD simulations of assembled binary supraballs.

Fig. 3 Supraballs and films assembled from binary 219/217nm SPs/SMPs.

Fig. 2 Supraballs and films from binary SPs.

Fig. 3 Performance of the generative model G, with and without stack-augmented memory. Performance of the generative model G, with and without stack-augmented.

Fig. 4 Behavior of resistance peak near density nm = 5.

Fig. 2 Comparison between the different reflective metasurface proposals when θi = 0° and θr = 70°. Comparison between the different reflective metasurface.

Presentation transcript:

Fig. 1 Microstructure of bulk UFG/nanocrystalline Cu-containing distributed WC nanoparticles. Microstructure of bulk UFG/nanocrystalline Cu-containing distributed WC nanoparticles. (A) SEM image of Cu-5vol%WC (by a cooling rate of 4 K/s) acquired at 52° showing well-dispersed WC nanoparticles in the Cu matrix. Inset is the image of a typical as-cast bulk Cu-5vol%WC ingot with a diameter of 50 mm. (B) Magnified SEM image of Cu-5vol%WC (4 K/s) showing the ultrafine and nanoscale Cu grains. (C) SEM image of the cross-section showing the UFG Cu matrix and the WC nanoparticles present beneath the surface of the sample. (D) Typical FIB image of Cu-5vol%WC (4 K/s) showing the UFG/nanocrystalline microstructure. (E) FIB image of pure Cu cast under the same condition showing coarse Cu grains. (F) EBSD image of Cu-5vol%WC (4 K/s) with grain size color code. Black phases are WC nanoparticles, red grains are smaller than 100 nm, and yellow and orange grains are smaller than 1 μm. (G) Summary of the average Cu grain sizes for different volume fractions of nanoparticles under different cooling rates. Error bars show the SD. Chezheng Cao et al. Sci Adv 2019;5:eaaw2398 Copyright © 2019 The Authors, some rights reserved; exclusive licensee American Association for the Advancement of Science. No claim to original U.S. Government Works. Distributed under a Creative Commons Attribution NonCommercial License 4.0 (CC BY-NC).