Prospects and challenges of perovskite type transparent conductive oxides in photovoltaic applications. Part II – Synthesis and deposition

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3 Citations (Scopus)

Abstract

Perovskite structured materials are gaining recognisant due to some of its favorable properties. A perovskite can be made into a transparent conductive oxides (TCO) and with doped materials that reduce its resistivity while maintaining high transparency it. Perovskites can be synthesized in many methods, which are solid state reaction, sol-gel, pechini and hydrothermal methods. However, each of the methods does have their own set of drawbacks to consider. The deposition method of perovskite material onto its substrate is also important since there are also several film deposition methods available for a perovskite. The different methods of deposition on perovskite TCO as well as other deposition method that have yet seen were also explained in this paper. A perovskite-structured material as a TCO does have its challenges from synthesis stage through the deposition stage as well as attempts to improve their optoelectric properties and the issues were discussed at the end of this paper.

Original languageEnglish
Pages (from-to)309-317
Number of pages9
JournalSolar Energy
Volume139
DOIs
Publication statusPublished - 1 Dec 2016

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Perovskite
Oxides
Solid state reactions
Transparency
Sol-gels
perovskite
Substrates

Keywords

  • Deposition
  • Hydrothermal
  • Perovskites
  • Sol-gel
  • Solid state reaction
  • Transparent conductive films

ASJC Scopus subject areas

  • Renewable Energy, Sustainability and the Environment
  • Materials Science(all)

Cite this

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title = "Prospects and challenges of perovskite type transparent conductive oxides in photovoltaic applications. Part II – Synthesis and deposition",
abstract = "Perovskite structured materials are gaining recognisant due to some of its favorable properties. A perovskite can be made into a transparent conductive oxides (TCO) and with doped materials that reduce its resistivity while maintaining high transparency it. Perovskites can be synthesized in many methods, which are solid state reaction, sol-gel, pechini and hydrothermal methods. However, each of the methods does have their own set of drawbacks to consider. The deposition method of perovskite material onto its substrate is also important since there are also several film deposition methods available for a perovskite. The different methods of deposition on perovskite TCO as well as other deposition method that have yet seen were also explained in this paper. A perovskite-structured material as a TCO does have its challenges from synthesis stage through the deposition stage as well as attempts to improve their optoelectric properties and the issues were discussed at the end of this paper.",
keywords = "Deposition, Hydrothermal, Perovskites, Sol-gel, Solid state reaction, Transparent conductive films",
author = "Riza, {Muhammad Arif} and Ibrahim, {Mohd. Adib} and Ahamefula, {Ubani Charles} and {Mat Teridi}, {Mohd Asri} and {Ahmad Ludin}, Norasikin and Suhaila Sepeai and Kamaruzzaman Sopian",
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T1 - Prospects and challenges of perovskite type transparent conductive oxides in photovoltaic applications. Part II – Synthesis and deposition

AU - Riza, Muhammad Arif

AU - Ibrahim, Mohd. Adib

AU - Ahamefula, Ubani Charles

AU - Mat Teridi, Mohd Asri

AU - Ahmad Ludin, Norasikin

AU - Sepeai, Suhaila

AU - Sopian, Kamaruzzaman

PY - 2016/12/1

Y1 - 2016/12/1

N2 - Perovskite structured materials are gaining recognisant due to some of its favorable properties. A perovskite can be made into a transparent conductive oxides (TCO) and with doped materials that reduce its resistivity while maintaining high transparency it. Perovskites can be synthesized in many methods, which are solid state reaction, sol-gel, pechini and hydrothermal methods. However, each of the methods does have their own set of drawbacks to consider. The deposition method of perovskite material onto its substrate is also important since there are also several film deposition methods available for a perovskite. The different methods of deposition on perovskite TCO as well as other deposition method that have yet seen were also explained in this paper. A perovskite-structured material as a TCO does have its challenges from synthesis stage through the deposition stage as well as attempts to improve their optoelectric properties and the issues were discussed at the end of this paper.

AB - Perovskite structured materials are gaining recognisant due to some of its favorable properties. A perovskite can be made into a transparent conductive oxides (TCO) and with doped materials that reduce its resistivity while maintaining high transparency it. Perovskites can be synthesized in many methods, which are solid state reaction, sol-gel, pechini and hydrothermal methods. However, each of the methods does have their own set of drawbacks to consider. The deposition method of perovskite material onto its substrate is also important since there are also several film deposition methods available for a perovskite. The different methods of deposition on perovskite TCO as well as other deposition method that have yet seen were also explained in this paper. A perovskite-structured material as a TCO does have its challenges from synthesis stage through the deposition stage as well as attempts to improve their optoelectric properties and the issues were discussed at the end of this paper.

KW - Deposition

KW - Hydrothermal

KW - Perovskites

KW - Sol-gel

KW - Solid state reaction

KW - Transparent conductive films

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JF - Solar Energy

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