Difference between revisions of "Low temperature sintered TiO2 porous layer"
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Conventionally it requires 450˚C to 500˚C to sinter the TiO2 porous layer which functioning as the photo-electrode in dye sensitized solar cell, it eliminates the participation of textile or plastic substrates due to its low heat resistance. | Conventionally it requires 450˚C to 500˚C to sinter the TiO2 porous layer which functioning as the photo-electrode in dye sensitized solar cell, it eliminates the participation of textile or plastic substrates due to its low heat resistance. | ||
− | === | + | ===150˚C sintering with UV assist=== |
− | <gallery> | + | <gallery mode="traditionall" class="left" caption="150˚C sintering with UV assist"> |
− | File:experiment setting of 18NR-T TiO2 paste during UV sintering.jpg | + | File:experiment setting of 18NR-T TiO2 paste during UV sintering.jpg|experiment setting. |
− | File:temperature measuring of 18NR-T TiO2 paste during UV sintering.jpg | + | File:temperature measuring of 18NR-T TiO2 paste during UV sintering.jpg|temperature measuring. |
− | File:18NR-T TiO2 paste during UV sintering.jpg | + | File:18NR-T TiO2 paste during UV sintering.jpg|The sample is put on a heat plate and exposed under the UV mercury tube. |
− | File:18NR-T TiO2 paste during UV sintering2.jpg | + | File:18NR-T TiO2 paste during UV sintering2.jpg|The result |
</gallery> | </gallery> | ||
Revision as of 15:48, 21 October 2023
Why
Conventionally it requires 450˚C to 500˚C to sinter the TiO2 porous layer which functioning as the photo-electrode in dye sensitized solar cell, it eliminates the participation of textile or plastic substrates due to its low heat resistance.
150˚C sintering with UV assist
HCL additive in TiO2 paste
References
- Lewis, Larry, James Spivack, Shellie Gasaway, Eric Williams, John Gui, Venkatesan Manivannan, and Oltea Siclovan. 2006. “A Novel UV-Mediated Low-Temperature Sintering of TiO 2 for Dye-Sensitized Solar Cells.” Solar Energy Materials and Solar Cells - SOLAR ENERG MATER SOLAR CELLS 90 (May): 1041–51. https://doi.org/10.1016/j.solmat.2005.05.019.
- Lin, Yu Hsein, Yung Chun Wu, Hsin Chiang You, Ping Hua Chen, Yi He Tsai, and Bo Yu Lai. 2014. “Ultra-Low Temperature Flexible Dye-Sensitized Solar Cell.” In 2014 International Symposium on Computer, Consumer and Control, 470–73. Taichung, Taiwan: IEEE. https://doi.org/10.1109/IS3C.2014.129.
- Holliman, Peter J., Dhiyaa K. Muslem, Eurig W. Jones, Arthur Connell, Matthew L. Davies, Cecile Charbonneau, Matthew J. Carnie, and David A. Worsley. 2014. “Low Temperature Sintering of Binder-Containing TiO2/Metal Peroxide Pastes for Dye-Sensitized Solar Cells.” Journal of Materials Chemistry A 2 (29): 11134–43. https://doi.org/10.1039/C4TA01000K.
- Zen, Shungo, Yuta Ishibashi, and Ryo Ono. 2014. “Low-Temperature Sintering for Plastic Dye-Sensitized Solar Cells Using Conventional TiO2 Paste Containing Organic Binders.” Applied Physics Letters 104 (21): 213904. https://doi.org/10.1063/1.4880117.
- Oh, Yeonjun, Sung-Nam Lee, Han-Ki Kim, and Jihoon Kim. 2012. “UV-Assisted Chemical Sintering of Inkjet-Printed TiO 2 Photoelectrodes for Low-Temperature Flexible Dye-Sensitized Solar Cells.” Journal of The Electrochemical Society 159 (10): H777–81. https://doi.org/10.1149/2.011210jes.
- NIKLAS D.J. HANSEN. (2014). MICROWAVE ASSISTED SYNTHESIS OF TITANIUM DIOXIDE ELECTRODES FOR USE IN POLYMER DSSC MICROWAVE ASSISTED SYNTHESIS OF TITANIUM DIOXIDE ELECTRODES FOR USE IN POLYMER DSSC