New insight into the spatio-temporal patterns of functional groups of hotspot inside the composting aggregates by synchrotron-based FTIR in hyperthermophilic composting

Hyperthermophilic composting (HTC) is a recently developed and highly promising organic fraction of municipal solid waste (OFMSW) treatment technology. Investigation of organic matter (OM) dynamics in compost particle is thus crucial for the understanding of humification of HTC process. Herein, this...

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Bibliographic Details
Published in:The Science of the total environment 2024-10, Vol.945, p.174139, Article 174139
Main Authors: Yang, Mingchao, Zhang, Tao, Zhou, Xuefei, Jin, Chenxi, You, Xiaogang, Zhang, Lei, Yang, Yinchuan, Kong, Zhe, Chu, Huaqiang, Zhang, Yalei
Format: Article
Language:English
Subjects:
2D-COS
Compost particles
Hyperthermophilic composting
SR-FTIR spectroscopy
μ-FTIR
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Summary:Hyperthermophilic composting (HTC) is a recently developed and highly promising organic fraction of municipal solid waste (OFMSW) treatment technology. Investigation of organic matter (OM) dynamics in compost particle is thus crucial for the understanding of humification of HTC process. Herein, this work aimed to study the chemical and structural changes of OM at the molecular level during HTC of OFMSW using EEM and SR-FTIR analyses. Additionally, two-dimensional correlation spectroscopy (2D-COS) was also utilized to probe and identify the changes in chemical constituents and functional groups of organic compounds on the surface of compost particles during different composting periods. Results show that SR-FTIR can detect fine-scale (~μm) changes in functional groups from the edges to the interior of compost particles during different composting periods by mapping the particles in situ. In the hyperthermophilic stage (day 9), the extracted μ-FTIR spectrum reveals a distinct boundary between anaerobic and aerobic regions within the compost particle, with a thickness of anaerobic zone (1460 cm−1) of approximately 30 μm inside the particle's core. This provides direct evidence of anaerobic trends at compost microscales level within compost particles. 2D-COS analysis indicated that organic functional groups gradually agglomerated in the order of 1330 > 2930 > 3320 > 1600 > 1030 > 895 cm−1 to the core skeleton of cellulose degradation residues, forming compost aggregates with well physicochemical properties. Overall, the first combination of SR-FTIR and EEM provides complementary explanations for the humification mechanism of HTC, potentially introducing a novel methodology for investigating the environmental behaviors and fates of various organic contaminants associated with OM during the in-situ composting biochemical process. [Display omitted] •Dynamic characterization of functional groups on compost particles was explored by EEM and SR-FTIR•A 30μm anaerobic zone was present in a composting particle in the hyperthermophilic stage.•SR-FTIR with 2DCOS reveals humification dynamics in micron-level.•Macro- and micro-scopic chemical imaging techniques verified the dynamic humification process.•Enhanced aeration during the thermophilic phase is recommended for substrates rich in solubles.
ISSN:0048-9697
1879-1026
1879-1026
DOI:10.1016/j.scitotenv.2024.174139