Fabrication, electrical and optical properties of silver, indium tin oxide (ITO), and indium zinc oxide (IZO) nanostructure arrays

    Authors

    A. A. Khosroabadi; P. Gangopadhyay; B. Duong; J. Thomas; A. K. Sigdel; J. J. Berry; T. Gennett; N. Peyghambarian;R. A. Norwood

    Comments

    Authors: contact us about adding a copy of your work at STARS@ucf.edu

    Abbreviated Journal Title

    Phys. Status Solidi A-Appl. Mat.

    Keywords

    carrier concentration; electrodes; interfaces; ITO; IZO; nanopillars; nanostructures; THIN-FILMS; SOLAR-CELLS; NANOWIRE ARRAYS; DEVICES; GROWTH; Materials Science, Multidisciplinary; Physics, Applied; Physics, ; Condensed Matter

    Abstract

    In thin film devices such as light-emitting diodes, photovoltaic cells and field-effect transistors, the processes of charge injection, charge transport, charge recombination, separation and collection are critical to performance. Most of these processes are relevant to nanoscale metal and metal oxide electrodeorganic material interfacial phenomena. In this report we present a unique method for creating tailored one-dimensional nanostructured silver, tin and/or zinc substituted indium oxide electrode structures over large areas. The method allows production of high aspect ratio nanoscale structures with feature sizes below 100nm and a large range of dimensional tunability. We observed that both the electronic and optical properties of these electrodes are closely correlated to the nanostructure dimensions and can be easily tuned by control of the feature size. Surface area enhancement accurately describes the conductivity studies, while nanostructure dependent optical properties highlight the quasi-plasmonic nature of the electrodes. Optimization of the nanostructured electrode transparency and conductivity for specific opto-electronic systems is expected to provide improvement in device performance.

    Journal Title

    Physica Status Solidi a-Applications and Materials Science

    Volume

    210

    Issue/Number

    5

    Publication Date

    1-1-2013

    Document Type

    Article

    Language

    English

    First Page

    831

    Last Page

    838

    WOS Identifier

    WOS:000319151900001

    ISSN

    1862-6300

    Share

    COinS