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.

Slides:

Advertisements

Similar presentations

Hierarchical MoS 2 tubular structures internally wired by carbon nanotubes as a highly stable anode material for lithium-ion batteries by Yu Ming Chen,

Advertisements

Fabrication of bilayer actuator composed of a hygroscopically active layer with aligned nanofibers and an inactive layer. Fabrication of bilayer actuator.

Fig. 4 Pupil shape and image quality in the model sheep eye.

Fig. 1 Cyclic voltammetric and electrochemical modeling of KOH-LiOH-CoO eutectic systems. Cyclic voltammetric and electrochemical modeling of KOH-LiOH-CoO.

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. 2 Effects of DMS responsiveness and nesting behavior on plastic ingestion in procellariiform seabirds. Effects of DMS responsiveness and nesting behavior.

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 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.

Fig. 2 General properties of Nafion/PVDF membranes.

Fig. 3 The dielectric properties and microwave heating response of CNT-loaded PLA films are probed as a function of nanotube loading. The dielectric properties.

Fig. 1 Bands and hybridization in graphene-encapsulated WSe2 measured by μ-ARPES. Bands and hybridization in graphene-encapsulated WSe2 measured by μ-ARPES.

Fig. 2 Fluidic and electrical characteristics of the wireless optofluidic system. Fluidic and electrical characteristics of the wireless optofluidic system.

Fig. 5 Acute monitoring of ICT and ICP in rats.

Fig. 4 Coatings on different substrates.

Fig. 2 Fluence-dependent emission characteristics of CH3NH3PbI3 recorded at 15 and 300 K. Fluence-dependent emission characteristics of CH3NH3PbI3 recorded.

Fig. 1 TED design and fabrication process.

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. 5 Electrochemical performance of stretchable aqueous rechargeable lithium-ion battery using a GAP multilayer conductor as a current collector. Electrochemical.

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. 3 Characteristics of UV and temperature sensors.

Fig. 2 Implantation procedure for the NET probes.

Fig. 5 PEDOT-infused leaves.

Fig. 2 Characteristics of the ReRAM and FETs.

The microchip-based drug delivery device and overview of study design

Self-powered textile for wearable electronics by hybridizing fiber-shaped nanogenerators, solar cells, and supercapacitors by Zhen Wen, Min-Hsin Yeh, Hengyu.

Fig. 1 Structure of L10-IrMn.

The prototype and working mechanism.

Fig. 4 Flexible OLED display driven by MoS2 backplane circuitry.

Fig. 4 Experimental outputs.

Characteristics of ultrathin single-crystalline semiconductor films

Fig. 4 Structural design of an F-TENG.

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

Fig. 2 Electrical and scanning probe characterization.

Fig. 3 The bacteria loading capacity and biocompatibility of GA/Pt.

Three-dimensional graphene/Pt nanoparticle composites as freestanding anode for enhancing performance of microbial fuel cells by Shenlong Zhao, Yuchen.

Fig. 1 A hollow polymer fiber filled with solid gallium creates a tough metamaterial core-shell fiber. A hollow polymer fiber filled with solid gallium.

Fabrication of metal origami structures.

Fig. 2 Structural design of an F-DSSC.

Fig. 2 Stabilizing the lithium-electrolyte interface.

Illustration of optogenetic cell stimulation with OLED microarrays

Fig. 7 Semiquantitative model of the knitted textile actuators.

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

Fig. 5 Demonstrations of the saTENG for large-area energy conversion and to harvest energy, using flowing water as the electrode. Demonstrations of the.

Fig. 3 Plastic ingestion and DMS responsiveness among procellariiform seabirds. Plastic ingestion and DMS responsiveness among procellariiform seabirds.

Enhanced PEDOT adhesion on solid substrates with electrografted P(EDOT-NH2)‏ by Liangqi Ouyang, Bin Wei, Chin-chen Kuo, Sheevangi Pathak, Brendan Farrell,

Fig. 2 The influence of TPP on the flammability of the electrolyte and the electrochemical performance of the graphite anode. The influence of TPP on the.

Fig. 4 Perovskite-infused nanoporous thin films for LEDs.

Fig. 5 Soft, smart contact lens for detecting glucose.

Fig. 3 MXene TLs and their attenuations.

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

Thermomechanical characterization of the elasticity and plasticity

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. 5 Distributions of cell nuclear area values and internuclear distances in the breast tumor specimens (Figs. 3 and 4), where bin interval = 8 and n.

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. 4 Relationship of plastic ingestion and nesting behavior.

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. 1 FETs constructed from densely packed semiconducting CNT arrays.

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

Fig. 2 Design and characterization of rGO-Na anode.

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

Fig. 2 Printed three-axis acceleration sensor.

Presentation transcript:

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 as the counter electrode and the TiO2 nanotube fiber as the photo anode. 3D graphene-RACNT fiber as the counter electrode for wire-shaped DSSCs. (A) Schematic representation of wire-shaped DSSC using 3D graphene-CNT fiber as the counter electrode and the TiO2 nanotube fiber as the photo anode. (B) Schematic drawing for the cross-section view of the wire-shaped DSSC. (C) SEM image of the cross-section view of the wire-shaped DSSC. (D) Photograph of the wire-shaped DSSC sealed in a glass capillary tube. (E) Flexible wire-shaped DSSC sealed in a transparent FET plastic tube. (F) Knot made from the flexible DSSC. (G) Current density–voltage characteristics of DSSCs with graphene wire, CNT wire, Pt wire, or 3D graphene-RACNT fiber as the counter electrode. (H) Nyquist plots of the 3D graphene-CNT fiber and the Pt wire measured in the I−/I3− electrolyte (10 mM LiI + 1 mM I2 + 0.1 M LiClO4 + acetonitrile). (I) Current density–voltage characteristics of DSSCs with the 3D graphene-RACNT wire counter electrode before and after bending. Yuhua Xue et al. Sci Adv 2015;1:e1400198 Copyright © 2015, The Authors