Publication Type : Journal Article
Publisher : ACS Applied Materials Interfaces
Source : ACS Applied Materials & Interfaces, Volume 5, Number 2, p.444-450 (2013)
Url : http://dx.doi.org/10.1021/am3025454
Campus : Coimbatore
School : Center for Industrial Research and Innovation
Center : Center for Industrial Research and Innovation (ACIRI)
Verified : Yes
Year : 2013
Abstract : Nanoclay minerals play a promising role as additives in the liquid electrolyte to form a gel electrolyte for quasi-solid-state dye-sensitized solar cells, because of the high chemical stability, unique swelling capability, ion exchange capacity, and rheological properties of nanoclays. Here, we report the improved performance of a quasi-solid-state gel electrolyte that is made from a liquid electrolyte and synthetic nitrate-hydrotalcite nanoclay. Charge transport mechanisms in the gel electrolyte and nanoclay interactions with TiO2/electrolyte interface are discussed in detail. The electrochemical analysis reveals that the charge transport is solely based on physical diffusion at the ratio of [PMII]:[I2] = 10:1 (where PMII is 1-propyl-3-methylimidazolium iodide). The calculated physical diffusion coefficient shows that the diffusion of redox ions is not affected much by the viscosity of nanoclay gel. The addition of nitrate-hydrotalcite clay in the electrolyte has the effect of buffering the protonation process at the TiO2/electrolyte interface, resulting in an upward shift in the conduction band and a boost in open-circuit voltage (VOC). Higher VOC values with undiminished photocurrent is achieved with nitrate-hydrotalcite nanoclay gel electrolyte for organic as well as for inorganic dye (D35 and N719) systems. The efficiency for hydrotalcite clay gel electrolyte solar cells is increased by 10%, compared to that of the liquid electrolyte. The power conversion efficiency can reach 10.1% under 0.25 sun and 9.6% under full sun. This study demonstrates that nitrate-hydrotalcite nanoclay in the electrolyte not only solidifies the liquid electrolyte to prevent solvent leakage, but also facilitates the improvement in cell efficiency.
Cite this Research Publication : X. Wang, Kulkarni, S. A., Ito, B. Ieiri, Sudip Kumar Batabyal, Nonomura, K., Wong, C. Cheong, Grätzel, M., Mhaisalkar, S. G., and Uchida, S., “Nanoclay gelation approach towards improved dye-sensitized solar cell efficiencies: an investigation of charge transport and shift in TiO2 conduction band”, ACS Applied Materials & Interfaces, vol. 5, pp. 444-450, 2013.