Fig. 1 FETs constructed from densely packed semiconducting CNT arrays.

Slides:

Advertisements

Similar presentations

Nanotechnology تقانة الصغائر.

Advertisements

Fig. 1 Device structure, typical output performance, and cytocompatibility of BD-TENG. Device structure, typical output performance, and cytocompatibility.

Fig. 6 Knockdown of nestin impaired tendon repair and regeneration in a rat model of patellar tendon defect. Knockdown of nestin impaired tendon repair.

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

Fig. 2 APT reconstructed volumes of human dental enamel HAP nanowires showing intergranular Mg-rich ACP. APT reconstructed volumes of human dental enamel.

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

Fig. 2 Electronically conducting xylem wires.

Fig. 2 Reconfiguration of liquid metals into 3D structures.

Fig. 1 Characterization of the device structure.

Fig. 1 High-resolution printing of liquid metals.

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

Structural analysis of graphene-embedded FeN4 (FeN4/GN) catalysts

Fig. 1 NP-free Ch-CNC droplets.

Fig. 3 Mechanism and result of the super-resolution RLP.

Fig. 3 Adhesion of water on two kinds of hot hydrophobic nanotexture.

Fig. 3 Piezoresistive e-skin with interlocked microdome arrays for simultaneous detection of static pressure and temperature. Piezoresistive e-skin with.

Fig. 1 Cryo-EM structure of yeast Elp123 showing its active site.

Fig. 5 The gate voltage dependence of IEE of the Rashba-split 2DEG between SrTiO3 and 3-UC LaAlO3. The gate voltage dependence of IEE of the Rashba-split.

Fig. 1 Device structure, typical output performance, and cytocompatibility of BD-TENG. Device structure, typical output performance, and cytocompatibility.

Fig. 1 The structure of the 3DGraphene foam.

Fig. 4 Transfer characteristics of the carristor.

Fig. 3 Extension of our proposed programmable synthesis to the selective synthesis of a wide variety of liposome/metal hybrids. Extension of our proposed.

Fig. 4 The performance of quasi–solid state Na-CO2 batteries with rGO-Na anodes. The performance of quasi–solid state Na-CO2 batteries with rGO-Na anodes.

Fig. 2 Implantation procedure for the NET probes.

Fig. 2 Broadband IR s-SNOM of large crystallites.

Fig. 2 Images of complex structures formed via sequential folding.

Fig. 1 A monolayer ReSe2 on a back-gated G/h-BN device.

Fig. 2 HRTEM and SEM images of RuO2 nanowires and electrical measurement circuit. HRTEM and SEM images of RuO2 nanowires and electrical measurement circuit.

Fig. 4 Experimental outputs.

Fig. 2 Gate and magnetic field dependence of the edge conduction.

Fig. 3 HfSe2 transistors. HfSe2 transistors. (A) Schematic of HfSe2 device, back-gated through 90-nm SiO2, and with ALD alumina used as both protective.

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

Fig. 1 Structure and absorption spectra of the P

Illustration of MIS-C and the characterization of the device structure

Fig. 2 Large-area and high-density assembly of AuNPs.

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

Fig. 2 Electrical and scanning probe characterization.

Fig. 1 Optical and STEM characterization of vdW heterostructures.

Fig. 4 Giant optical chirality.

Fig. 1 Schematic view and characterizations of FGT/Pt bilayer.

Fig. 2 Comparison of 1L, 2L, and 3L single crystals.

Fig. 2 Structural design of an F-DSSC.

Fig. 2 Electrical properties of CNT array FETs and influence of postdeposition treatment on conductance. Electrical properties of CNT array FETs and influence.

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

HfSe2 and ZrSe2: Two-dimensional semiconductors with native high-κ oxides by Michal J. Mleczko, Chaofan Zhang, Hye Ryoung Lee, Hsueh-Hui Kuo, Blanka Magyari-Köpe,

Fig. 1 Experimental strategy and elemental and morphological analysis of 3D/2D perovskite bilayer. Experimental strategy and elemental and morphological.

Fig. 5 Benchmarking CNT array FET performance against Si MOSFETs.

Fig. 4 Comparison of different catalyst loading methods and substrates in the cathode of a PEMEC (one is on the membrane and the other one is on the LGDL).

Perovskite nanowire–block copolymer supramolecular nanocomposites

Fig. 2 Temperature-sensing properties of the flexible rGO/PVDF nanocomposite film. Temperature-sensing properties of the flexible rGO/PVDF nanocomposite.

Fig. 1 Sketch and schematic diagram of photobleaching reaction in a strongly coupled system. Sketch and schematic diagram of photobleaching reaction in.

Fig. 3 Spectroscopic characterization of postdeposition treatments.

Fig. 4 Single-particle contact angle measurements.

Fig. 6 MD simulations of assembled binary supraballs.

Fig. 3 Performance of the solid wire supercapacitors of 3D graphene-CNT fiber for energy storage. Performance of the solid wire supercapacitors of 3D graphene-CNT.

Fig. 2 Structural information.

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

Fig. 2 Supraballs and films from binary SPs.

SEM and TEM images and photoluminescence properties of composites

Fig. 1 Design principle and SEM characterization of super-origami DNA nanostructures with n-tuples. Design principle and SEM characterization of super-origami.

Fig. 4 Reconstruction of the nematocysts in Nematodinium sp.

Fig. 4 Characterization and SERS spectra of tetrameric metamolecules.

Fig. 2 Fibrous structure, roughness, and softness of SNE surface enabling switchable adhesion. Fibrous structure, roughness, and softness of SNE surface.

Fig. 3 Switchable adhesion influenced by structural design and object conductivity. Switchable adhesion influenced by structural design and object conductivity.

Fig. 5 Electrical stimulation of nerve cells powered by BD-TENG.

Fig. 4 “Editing”—Write-erase-rewrite using PLE.

Fig. 4 3D graphene-RACNT fiber as the counter electrode for wire-shaped DSSCs. (A) Schematic representation of wire-shaped DSSC using 3D graphene-CNT fiber.

Fig. 5 SEM images of pin and disc wear tests.

Fig. 1 The anisotropic charge transport in the bulk and the spontaneous formation of Cu–Mo–S–based dense nanocomposites during deposition of MoS2 directly.

Fig. 2 Printed three-axis acceleration sensor.

Presentation transcript:

Fig. 1 FETs constructed from densely packed semiconducting CNT arrays. FETs constructed from densely packed semiconducting CNT arrays. (A) Schematic of CNT array sitting on a SiO2/Si back gate (G) with top Pd source (S) and drain (D) electrodes. (B) False-colored SEM image of a representative FET highlighting where the contacts overlap the CNT array (light orange) and the CNT array channel (dark orange), with Wch = 4.1 μm and Lch = 150 nm. Inset SEM image (scale bar, 200 nm) shows the CNT array, with 47 CNTs μm−1 and a high degree of alignment. (C) TEM cross-sectional image of Pd/CNT/SiO2 electrode stack where the “humps” in the Pd correspond to CNTs in the array. High-resolution TEM images reveal individual CNTs underneath the Pd “humps” with a diameter of 1.3 to 1.9 nm. (D) Atomic force miscroscopy image of 30 nm of Pd overcoating a CNT array, evidencing the conformity of the Pd to the individual CNTs. Gerald J. Brady et al. Sci Adv 2016;2:e1601240 Copyright © 2016, The Authors