Your search keyword '"BIOCHAR"' showing total 2 results

1. Biochar activated by oxygen plasma for supercapacitors.

Author

Gupta, Rakesh Kumar, Dubey, Mukul, Kharel, Parashu, Gu, Zhengrong, and Fan, Qi Hua

Subjects

*BIOCHAR, *OXYGEN plasmas, *SUPERCAPACITORS, *CARBON-black, *BIOMASS energy, *PYROLYSIS

Abstract

Biochar, also known as black carbon, is a byproduct of biomass pyrolysis. As a low-cost, environmental-friendly material, biochar has the potential to replace more expensive synthesized carbon nanomaterials (e.g. carbon nanotubes) for use in future supercapacitors. To achieve high capacitance, biochar requires proper activation. A conventional approach involves mixing biochar with a strong base and baking at a high temperature. However, this process is time consuming and energy inefficient (requiring temperatures >900 °C). This work demonstrates a low-temperature (<150 °C) plasma treatment that efficiently activates a yellow pine biochar. Particularly, the effects of oxygen plasma on the biochar microstructure and supercapacitor characteristics are studied. Significant enhancement of the capacitance is achieved: 171.4 F g −1 for a 5-min oxygen plasma activation, in comparison to 99.5 F g −1 for a conventional chemical activation and 60.4 F g −1 for untreated biochar. This enhancement of the charge storage capacity is attributed to the creation of a broad distribution in pore size and a larger surface area. The plasma activation mechanisms in terms of the evolution of the biochar surface and microstructure are further discussed. [ABSTRACT FROM AUTHOR]

Published

2015

2. Utilization of corn cob biochar in a direct carbon fuel cell.

Author

Yu, Jinshuai, Zhao, Yicheng, and Li, Yongdan

Subjects

*DIRECT carbon fuel cells, *BIOCHAR, *CORNCOBS, *BIOMASS energy, *CARBON cycle, *MOLTEN carbonate fuel cells

Abstract

Biochar obtained from the pyrolysis of corn cob is used as the fuel of a direct carbon fuel cell (DCFC) employing a composite electrolyte composed of a samarium doped ceria (SDC) and a eutectic carbonate phase. An anode layer made of NiO and SDC is utilized to suppress the cathode corrosion by the molten carbonate and improves the whole cell stability. The anode off-gas of the fuel cell is analyzed with a gas chromatograph. The effect of working temperature on the cell resistance and power output is examined. The maximum power output achieves 185 mW cm −2 at a current density of 340 mA cm −2 and 750 °C. An anode reaction scheme including the Boudouard reaction is proposed. [ABSTRACT FROM AUTHOR]

Published

2014