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Biochar production from flocculent and granular sludge : revealing the roles of inorganics originated from seawater

Authors :
Chen, Guanghao
Hao, Tianwei
Li, Xiling
Chen, Guanghao
Hao, Tianwei
Li, Xiling
Publication Year :
2020

Abstract

Biochar production from organic wastes is a promising way to achieve both waste minimization and resource recovery and relies on the pyrolysis process fixing carbon in solid-state. As a result, the fixation of carbon reduces the greenhouse gas emission, while the produced biochar can be effectively reused as a resource in the agricultural industry, building sector, water treatment facilities, etc. However, biochar production from waste activated sludge is limited due to high energy requirements and low product quality. A “seawater-in-sludge” approach was first proposed in this thesis to modify the biochar properties produced from sewage sludge. The biochar yield was found to be increased by 10% when more alkali and alkaline earth metals (AAEM) species were incorporated into the sludge matrix from seawater. The nitrogen-sorption isotherm indicated a higher specific surface area of biochar (480.3 m2/g) obtained from the minerals loaded sludge at high temperatures, showing activation effects. Raman spectroscopy and X-ray photoelectron spectroscopy (XPS) revealed that minerals activation increased the graphitization degree of the carbon structure and decreased the surface functional groups. This lead to lower resistance and a higher capacitance of 113.9 F/g of the carbon electrodes (60% higher than the control groups without seawater). Despite the merits of AAEM cations on biochar surfaces, the roles of them during sludge pyrolysis remain unclear. Granulation of conventional flocculent sludge is a natural enrichment of AAEM cations and the formed granular sludge would exhibit distinct pyrolysis behaviour from flocculent sludge. In such contexts, this study investigated the process kinetics and mechanisms of both flocculent and granular sludge in the second part. Granular sludge devolatilized from 210℃ was more thermally stable than flocculent sludge whose devolatilization started from 170 ℃. However, the activation energy required for granular sludge decompos

Details

Database :
OAIster
Notes :
English
Publication Type :
Electronic Resource
Accession number :
edsoai.on1363070881
Document Type :
Electronic Resource