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. 2018 Jul 10;15(7):1459.
doi: 10.3390/ijerph15071459.

Physicochemical Properties of Biochars Produced from Biosolids in Victoria, Australia

Yumeng Yang  1 Barry Meehan  2 Kalpit Shah  3 Aravind Surapaneni  4 Jeff Hughes  5 Leon Fouché  6 Jorge Paz-Ferreiro  7
Affiliations

Physicochemical Properties of Biochars Produced from Biosolids in Victoria, Australia

Yumeng Yang et al. Int J Environ Res Public Health. .

Abstract

Some of the barriers associated with the land application of biosolids generated in wastewater treatment plants can be eliminated simply by converting the biosolids into biochar using a thermal conversion process called “pyrolysis”. In the current work, eight biosolids from four different wastewater treatment plants in southeast Melbourne, Victoria, Australia were collected and pyrolysed to produce biochars at two different temperatures (500 and 700 °C). In addition, characterisation studies were carried out on the biochars to obtain their physicochemical properties, which were subsequently compared with the properties of the parent biosolids. The major findings of the work demonstrated that biochars exhibited large decreases in DTPA-extractable metals such as Cd, Cu, and Zn, and also led to favorable changes in several chemical and physical characteristics (i.e., pH, Olsen P, electrical conductivity, and surface area) for agricultural land application compared to their original form (i.e., biosolids). Overall, the study suggests that there is great potential for converting biosolids to biochar using pyrolysis. This may not only improve the properties of biosolids for land application, but also has potential to reduce the risk to receiving environments and, furthermore, eliminate many of the costly elements associated with biosolids stockpiling and management.

Keywords: biochar; biosolids; heavy metals; phosphorus; pyrolysis.

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Conflict of interest statement

The authors declare no conflicts of interest.

Figures

Figure 1
Figure 1
Stainless-steel mesh rolls with biosolids inside.
Figure 2
Figure 2
CharMaker commercial facility used for pyrolysing biosolids in this study.
See this image and copyright information in PMC

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