Media.Player

Silver Nanowire-Indium Tin Oxide Nanoparticle As A Transparent Conductor For Optoelectronic Devices

Technology Benefits

Improved wire-to-wire junction conductanceSmooth surface morphologyExcellent mechanical adhesionFlexible thin filmsSolution processable

Technology Application

Optoelectronic devicesThin film solar cellsLiquid crystal displaysTouch screensLight emitting diodes

Detailed Technology Description

Researchers led by Professor Yang Yang have developed a novel indium tin oxide (ITO) NP-AgNW composite thin film for transparent, flexible optoelectronic devices. This low temperature technique shows improved wire-to-wire junction conductance, smooth surface morphology, excellent mechanical adhesion and flexibility while maintaining the sheet resistance and transmittance values necessary to replace conventional sputtered ITO thin films. As a proof of concept, ITO NPs were embedded into a AgNW mesh, but this method can be further extended to other metal oxide NPs that are less expensive and more abundant, like aluminum doped zinc oxide and antimony doped tin oxide. This will result in a wide range of conductive metal oxide materials to use for a variety of optoelectronic devices.

Application No.

9560754

Others

State Of Development

Solution processed thin films of these materials have been formed and characterized. Prototype solar cells made from this material have been fabricated and are in the testing stage.

Background

For optoelectronic applications, such as liquid crystal devices, light emitting diodes, and thin-film solar cells, there is a need for flexible, transparent conductors that are easily processable under mild and ambient conditions. Current methods to fabricate conducting metal oxide thin films use complex and costly sputtering techniques that are not compatible with high-throughput roll-to-roll processing. Not only are these techniques not viable for flexible device application because the films formed are brittle and crack easily, but the heating involved can damage the underlying organic layers for organic-based optoelectronic devices. Recent research has focused on incorporating AgNW networks into the metal oxide film, but several issues need to be resolved, including the wire-to-wire junction resistance, surface roughness, and gaps between the nanowires, before they can be a practical option.

Related Materials

C. H. Chung, T. B. Song, B. Bob, R. Zhu, and Y. Yang. Solution-Processed Flexible Transparent Conductors Composed of Silver Nanowire Networks Embedded in Indium Tin Oxide Nanoparticle Matrices. Nano Research. 2012.

Additional Technologies by these Inventors

• High-throughput Solution Processing of Large Scale Graphene for Device Applications
• Solution-Deposition of CIGS Solar Cell by Spray-Coating
• Three-Terminal Organic Memory Devices
• Bottom Insulating Gate Vertical Organic Transistor
• Rewritable Nano-Surface Organic Electrical Bistable Devices
• Organic Electrical Bistable Devices Fabricated by Solution Processing
• Organic Bistable Device and Organic Memory Cells
• Solution Synthesis and Deposition of Kesterite Copper Zinc Tin Chalcogenide Films
• Polarizing Photovoltaic Device and its Application in Liquid Crystal Displays and Tandem Solar Cells
• Conjugated Polymers with Selenium Substituted Diketopyrrolopyrrole Unit for Electronics Devices
• Multiple Donor/Acceptor Bulk Heterojunction Solar Cells
• Au Nanoparticles Doped Polyaniline Nanofiber Non-Volatile Memory Device
• Titanium Oxide as the Window Layer for Metal Chalcogenide Photovoltaic Devices
• Novel Polymers For Polymer Solar Cells, Transistors, And Sensors
• Design Of Semi-Transparent, Transparent, Stacked Or Top-Illuminated Organic Photovoltaic Devices
• Amorphous Silicon And Polymer Hybrid Tandem Photovoltaic Cell
• Efficient And Stable Of Perovskite Solar Cells With All Solution Processed Metal Oxide Transporting Layers
• A Bi-Functional Lewis Base Additive For Microscopic Homogeneity In Perovskite Solar Cells

Tech ID/UC Case

27209/2012-113-0

Related Cases

2012-113-0

*Abstract

UCLA researchers in the Department of Materials Science and Engineering have developed a novel composite material made of metal oxide nanoparticles (NPs) and silver nanowires (AgNWs).

*IP Issue Date

Jan 31, 2017

*Principal Investigator

Name: Choong-Heui Chung

Department:

Name: Tze-Bin Song

Department:

Name: Yang Yang

Department:

Name: Rui Zhu

Department:

Country/Region

USA