AI Article Synopsis
- Composting is driven by microorganisms and can be boosted by adding biochar or specific microorganisms, as explored in a study comparing four different treatment methods for composting dewatered sludge waste and wheat straw.
- The study found that adding the newly isolated strain Xenophilus azovorans (XPA) or biochar-immobilized XPA (BCI-XPA) extended the thermophilic phase and improved seed germination, with BCI-XPA showing the highest effectiveness in enhancing microbial activity and diversity.
- Carbon emissions increased with treatments involving XPA and BCI-XPA, which also promoted the formation of humic acids and altered pathways for organic material degradation, indicating their potential to enhance composting efficiency.
Article Abstract
Composting is a biological reaction caused by microorganisms. Composting efficiency can be adequately increased by adding biochar and/or by inoculating with exogenous microorganisms. In this study, we looked at four methods for dewatered sludge waste (DSW) and wheat straw (WS) aerobic co-composting: T1 (no additive), T2 (5% biochar), T3 (5% of a newly isolated strain, Xenophilus azovorans (XPA)), and T4 (5% of biochar-immobilized XPA (BCI-XPA)). Throughout the course of the 42-day composting period, we looked into the carbon dynamics, humification, microbial community succession, and modifications to the driving pathways. Compared to T1 and T2, the addition of XPA (T3) and BCI-XPA (T4) extended the thermophilic phase of composting without negatively affecting compost maturation. Notably, T4 exhibited a higher seed germination index (132.14%). Different from T1 and T2 treatments, T3 and T4 treatments increased CO and CH emissions in the composting process, in which the cumulative CO emissions increased by 18.61-47.16%, and T3 and T4 treatments also promoted the formation of humic acid. Moreover, T4 treatment with BCI-XPA addition showed relatively higher activities of urease, polyphenol oxidase, and laccase, as well as a higher diversity of microorganisms compared to other processes. The Functional Annotation of Prokaryotic Taxa (FAPROTAX) analysis showed that microorganisms involved in the carbon cycle dominated the entire composting process in all treatments, with chemoheterotrophy and aerobic chemoheterotrophy being the main pathways of organic materials degradation. Moreover, the presence of XPA accelerated the breakdown of organic materials by catabolism of aromatic compounds and intracellular parasite pathways. On the other hand, the xylanolysis pathway was aided in the conversion of organic materials to dissolved organics by the addition of BCI-XPA. These findings indicate that XPA and BCI-XPA have potential as additives to improve the efficiency of dewatered sludge and wheat straw co-composting.
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| http://dx.doi.org/10.1016/j.jenvman.2024.121613 | DOI Listing |
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