Indian Journal of Pure and Applied Physics

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Carbon derived from Jute Sacks For Low-Cost and Efficient Counter Electrodes of Dye-Sensitized Solar Cells


Affiliations
1 Department of Physics, Patan Multiple Campus, Tribhuvan University 44700, Nepal
2 Materials Science, Engineering and Commercialization Program (MSEC), Texas State University, San Marcos TX 78666, United States
3 Department of Physics, Brooklyn College and the Graduate Center of the City University of New York, Brooklyn, NY 11210, United States
4 Department of Physics, Kathmandu University, 45200, Nepal
5 Department of Physics, Bhaktapur Multiple Campus, Tribhuvan University 44800, Nepal

Non-activated and activated carbons derived from jute sacks were used as counter electrode (CE) materials of dye-sensitized solar cells (DSSCs). The non-activated carbon sample was synthesized by carbonization of jute fibers at 600°C in N2. The activated carbon samples were synthesized by carbonizing the ZnCl2 activated jute at 600 and 800°C in N2. The x-ray diffraction revealed that the jute-based carbon samples comprised of graphitic and amorphous carbons. Raman spectroscopy disclosed that the disordered carbon was dominant in all samples. Based on the energy dispersive x-rays spectroscopy measurements, activated carbon prepared at 800 °C had the highest amount of carbon content (~94.3%). The surface textural properties of the samples were investigated with N2 adsorption-desorption experiment. Brunauer-Emmett-Teller surface area of non-activated (NACJ6), activated at 600 °C (ACJ6) and activated at 800 °C (ACJ8) carbon samples were 23.73, 1912, and 1613 m2g-1, respectively, and their corresponding pore volumes were 0.02448, 1.114 and 0.9625 cm3g-1, respectively. ACJ8 with the highest carbon content, moderately high surface area, and micropores and mesopores/macropores demonstrated superior catalytic ability among the samples. The efficiency of the light to electric power conversion of the DSSCs using ACJ8, ACJ6, and NACJ6 as CEs were found to be about 3.35, 2.75, and 0.88%, respectively, compared to 3.39% that of the DSSC using platinum (Pt). Obtained efficiency comparable to Pt based DSSC using the ACJ8 sample implies that the jute-based activated carbon can be an inexpensive and efficient CE material alternative to Pt for commercialization.

Keywords

Activated carbon; Counter electrode; Catalyst; DSSCs; Iodide/tri-iodide ions; Jute; Platinum
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  • Carbon derived from Jute Sacks For Low-Cost and Efficient Counter Electrodes of Dye-Sensitized Solar Cells

Abstract Views: 37  | 

Authors

Khom Narayan Chaudhary
Department of Physics, Patan Multiple Campus, Tribhuvan University 44700, Nepal
Sanjay Rimal
Department of Physics, Patan Multiple Campus, Tribhuvan University 44700, Nepal
Mohan Prasad Sapkota
Department of Physics, Patan Multiple Campus, Tribhuvan University 44700, Nepal
Anupam K C
Materials Science, Engineering and Commercialization Program (MSEC), Texas State University, San Marcos TX 78666, United States
Umesh Lawaju
Department of Physics, Patan Multiple Campus, Tribhuvan University 44700, Nepal
Mim Lal Nakarmi
Department of Physics, Brooklyn College and the Graduate Center of the City University of New York, Brooklyn, NY 11210, United States
Manoj Pandey
Department of Physics, Kathmandu University, 45200, Nepal
Prakash Joshi
Department of Physics, Bhaktapur Multiple Campus, Tribhuvan University 44800, Nepal

Abstract


Non-activated and activated carbons derived from jute sacks were used as counter electrode (CE) materials of dye-sensitized solar cells (DSSCs). The non-activated carbon sample was synthesized by carbonization of jute fibers at 600°C in N2. The activated carbon samples were synthesized by carbonizing the ZnCl2 activated jute at 600 and 800°C in N2. The x-ray diffraction revealed that the jute-based carbon samples comprised of graphitic and amorphous carbons. Raman spectroscopy disclosed that the disordered carbon was dominant in all samples. Based on the energy dispersive x-rays spectroscopy measurements, activated carbon prepared at 800 °C had the highest amount of carbon content (~94.3%). The surface textural properties of the samples were investigated with N2 adsorption-desorption experiment. Brunauer-Emmett-Teller surface area of non-activated (NACJ6), activated at 600 °C (ACJ6) and activated at 800 °C (ACJ8) carbon samples were 23.73, 1912, and 1613 m2g-1, respectively, and their corresponding pore volumes were 0.02448, 1.114 and 0.9625 cm3g-1, respectively. ACJ8 with the highest carbon content, moderately high surface area, and micropores and mesopores/macropores demonstrated superior catalytic ability among the samples. The efficiency of the light to electric power conversion of the DSSCs using ACJ8, ACJ6, and NACJ6 as CEs were found to be about 3.35, 2.75, and 0.88%, respectively, compared to 3.39% that of the DSSC using platinum (Pt). Obtained efficiency comparable to Pt based DSSC using the ACJ8 sample implies that the jute-based activated carbon can be an inexpensive and efficient CE material alternative to Pt for commercialization.

Keywords


Activated carbon; Counter electrode; Catalyst; DSSCs; Iodide/tri-iodide ions; Jute; Platinum