Ceramic Tiles with Photovoltaic Properties

Daliana Muller; Geneviève K. Pinheiro; Letícia T. Scarabelot; Jonathan F. França; Dachamir Hotza; Carlos R. Rambo

doi:10.4028/www.scientific.net/MSF.798-799.312

Paper Titles

Total and Partial Replacement of Quartz in Aluminum Hydroxides Porcelain Formulations
p.289

Study of the Effect of Feldspar Replacement from a Mixture of Glass / Syenite in Technological Properties of Ceramic Coatings
p.294

Characterization of Ceramic Composite Waste of Granite, Marble and Caulim for Production of Coating Plates
p.300

Analysis of Color of the Ceramic Coatings Submitted to Different Processing Conditions
p.306

Ceramic Tiles with Photovoltaic Properties
p.312

Reuse of Waste from Polish in the Production of Porcelain
p.317

Phases Obtained from Heat Treatment of Mn-Co-Based Coatings Deposited by Dip Coating
p.323

Formation of Spinel from Fe-Ni Coating Electrodeposited on AISI 430 Ferritic Stainless Steel
p.328

Morphology and Fluidity of Spray-Dried Powder Transported by Compressed Air
p.334

HomeMaterials Science ForumMaterials Science Forum Vols. 798-799Ceramic Tiles with Photovoltaic Properties

Ceramic Tiles with Photovoltaic Properties

Abstract:

The development of organic materials with photovoltaic properties should enable the production of polymeric solar cells with high conversion efficiency. Due to low production cost and conversion efficiency above 10%, organic solar cells have great potential to compete with inorganic photovoltaic cells. This work proposes the development and integration of ETA (extremely thin absorber) photovoltaic cells, based on titanium oxide films and nanostructured conductive polymer in ceramic tiles, with the purpose of increasing the available area for sunlight capture, normally limited to roofs, expanding it onto the lateral sides of buildings. The nanostructured TiO₂ was obtained by sol-gel process from titanium isopropoxide, followed by supercritical CO₂ extraction in order to obtain a nanostructured aerogel. The conductive polymer used was the poly-3.4 (ethylenedioxythiophene)/polystyrene sulfonate (PEDOT:PSS) synthesized with iron III p-toluene sulfonate as an oxidizing agent. The materials were deposited layer by layer on a Cu electrode mounted on a ceramic tile piece, covered with glass containing a thin conductive layer of indium doped tin oxide (ITO). Transmission electron microscopy (TEM) revealed that the nanostructured titania aerogels exhibit particle sizes in the range of 2-5 nm. Preliminary studies have shown that the developed solar cell show a behavior typical of diodes (characteristic I×V curve) when subjected to different wavelength lamps (fluorescent and UV). Ceramic wall and roof tiles with photovoltaic properties, independently of the conversion efficiency, could serve as auxiliary energy sources to reduce expenses with conventional electricity.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Materials Science Forum (Volumes 798-799)

Pages:

312-316

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.798-799.312

Citation:

Cite this paper

Online since:

June 2014

Authors:

Daliana Muller, Geneviève K. Pinheiro, Letícia T. Scarabelot, Jonathan F. França, Dachamir Hotza, Carlos R. Rambo

Keywords:

ETA Solar Cell, Hybrid Photovoltaic Systems, PEDOT:PSS, TiO₂ Aerogel

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] F.R. Martins, E.B. Pereira, S.A.B. Silva, S.L. Abreu and S. Colle: Ener. Policy Vol. 36 (2008), p.2853.

Google Scholar

[2] L. Baia, A. Peter, V. Cosoveanu, E. Indrea, M. Baia, J. Popp and V. Danciu: Thin Solid Films Vol. 511–512 (2006), p.512.

DOI: 10.1016/j.tsf.2005.12.024

Google Scholar

[3] K. -J. Kim, Y. -S. Kim, W. -S. Kang, B. -H. Kang, S. -H. Yeom, J. -H. Kim, S. -W. Kang: Sol. Ener. Mat. Sol. C Vol. 94 (2010), p.1303.

Google Scholar

[4] R. Könenkamp, P. Hoyer, A. Wahi: J. Appl. Phys. Vol. 79 (1996), p.7029.

Google Scholar

[5] J.D. Kwon, P.H. Kim, J.H. Keum, J.S. Kim: Sol. Ener. Mat. Sol. C Vol. 83 (2004), p.311.

Google Scholar

[6] Y. Iwai, T. Nakashima and S. Yonezawa: J. Supercritical Fluids Vol. 77 (2013), p.153.

Google Scholar

[7] Y.C. Chiang, W.Y. Cheng and S.Y. Lu: Int. J. Electrochem. Sci. Vol. 7 (2012), p.6910.

Google Scholar

[8] Y. Kima, J.W. Lima, Y.E. Sung, J.B. Xia, N. Masaki, S. Yanagida: J. Photoch. Photobio. A Vol. 204 (2009), p.110.

Google Scholar

[9] J. Yana, C. Sun, F. Tan, X. Hu, P. Chen, S. Qu, S. Zhoua, J. Xu: Sol. Ener. Mat. Sol. C Vol. 94 (2010), p.390.

Google Scholar

[10] C.H. Wu, T.M. Don and W.Y. Chiu: Polymer Vol. 52 (2011), p.1375.

Google Scholar

[11] Y.S. Kim, S.B. Oh, J.H. Park, M.S. Cho, Y. Lee: Sol. Ener. Mat. Sol. C Vol. 94 (2010), p.471.

Google Scholar

[12] H. Berger, H. Tang, F. Levy: J. Cryst. Growth Vol. 130 (1993), p.108.

Google Scholar

[13] S. Yuan, R. Mao, Y. Li, Q. Zhang, H. Wang: oxygen demand, Electrochim. Acta Vol. 60 (2012), p.347.

Google Scholar

[14] Y. -C. Chiang, W. -Y. Cheng and S. -Y. Lu: Int. J. Electrochem. Sci. Vol. 7 (2012), p.6910.

Google Scholar

[15] J.J. Pietron, A.M. Stux, R.S. Compton, D.R. Rolison: Sol. Ener. Mat. Sol. C Vol. 91 (2007), p.1066.

Google Scholar