TY - JOUR
T1 - Co-pyrolysis of sewage sludge and food waste digestate to synergistically improve biochar characteristics and heavy metals immobilization
AU - Wang, Xingdong
AU - Wei-Chung Chang, Victor
AU - Li, Zhiwei
AU - Song, Yang
AU - Li, Chunxing
AU - Wang, Yin
PY - 2022
Y1 - 2022
N2 - Food waste digestate (FWD) is a desirable additive in sewage sludge
(SS)-based biochar preparation owing to its high contents of intrinsic
inorganic minerals and lignocellulosic compounds. In this study, we
investigated the co-pyrolysis of SS with FWD at different mixing ratios
(4:0, 3:1, 2:2, 1:3, and 0:4; SS:FWD w/w) at 550 °C to synergistically
improve the biochar characteristics and immobilize the heavy metals in
the SS. The results showed that co-pyrolysis of SS with FWD greatly
increased the aromaticity and pH (by 13.22–26.56%) of the blended
biochar, and significantly reduced the contents of total and
bioavailable heavy metals. The addition of FWD effectively enhanced the
conversion of heavy metals from less stable fractions to more stable
forms, but led to the transformation of Cr from the residual fraction
(F4) to the oxidizable fraction (F3) when the FWD:SS ratio was ≥ 3:1.
Overall, the formation of co-crystal compounds, stable kaolinite, and
metal oxides together with the enhancement of biochar characteristics
during co-pyrolysis significantly reduced the heavy metal-associated
ecological risk (potential ecological risk index lower than 15.51) and
phytotoxicity (germination index higher than 139.41%) of the blended
biochar. These findings suggest that high levels of mineral components
in FWD greatly immobilize more heavy metals in biochar.
AB - Food waste digestate (FWD) is a desirable additive in sewage sludge
(SS)-based biochar preparation owing to its high contents of intrinsic
inorganic minerals and lignocellulosic compounds. In this study, we
investigated the co-pyrolysis of SS with FWD at different mixing ratios
(4:0, 3:1, 2:2, 1:3, and 0:4; SS:FWD w/w) at 550 °C to synergistically
improve the biochar characteristics and immobilize the heavy metals in
the SS. The results showed that co-pyrolysis of SS with FWD greatly
increased the aromaticity and pH (by 13.22–26.56%) of the blended
biochar, and significantly reduced the contents of total and
bioavailable heavy metals. The addition of FWD effectively enhanced the
conversion of heavy metals from less stable fractions to more stable
forms, but led to the transformation of Cr from the residual fraction
(F4) to the oxidizable fraction (F3) when the FWD:SS ratio was ≥ 3:1.
Overall, the formation of co-crystal compounds, stable kaolinite, and
metal oxides together with the enhancement of biochar characteristics
during co-pyrolysis significantly reduced the heavy metal-associated
ecological risk (potential ecological risk index lower than 15.51) and
phytotoxicity (germination index higher than 139.41%) of the blended
biochar. These findings suggest that high levels of mineral components
in FWD greatly immobilize more heavy metals in biochar.
KW - Co-pyrolysis
KW - Sewage sludge
KW - Food waste digestate
KW - Biochar
KW - Heavy metal
U2 - 10.1016/j.wasman.2022.02.001
DO - 10.1016/j.wasman.2022.02.001
M3 - Journal article
C2 - 35149479
SN - 0956-053X
VL - 141
SP - 231
EP - 239
JO - Waste Management
JF - Waste Management
ER -