Title:Carbon Transformations of Biochar Based Co-Composting - A Review
Volume: 18
Issue: 4
Author(s): Balaganesh Pandiyan, Vasudevan Mangottiri*Natarajan Narayanan
Affiliation:
- Department of Civil Engineering, Bannari Amman Institute of Technology, Sathyamangalam,India
Keywords:
Biochar carbon, co-composting, soil organic matter, carbon sequestration, nutrient mineralization, organic functional
group.
Abstract: Biochar-Amended Composting (BAC) plays an integral role in sustainable agricultural
practices due to its multiple benefits in crop production, soil nutrient retention, carbon sequestration
and environmental protection. Although accepted as a traditional method, there is a lack of
understanding in defining its suitability and efficiency in terms of various base-materials and conditions.
Being two carbon-based entities with plentiful nutrients and surface activity, biochar and
compost find application in agricultural fields together or separately for improving the soil properties
and crop productivity. Recent studies focus on defining the optimum conditions for their preparation,
mixing, application and monitoring under various feed, soil, crop and climatic conditions.
However, due to the complexity and specificity of the system, many influencing aspects of their
interaction are yet unknown in detail. In this review, we analyze the recent advancements in the
selection and preparation of new materials for BAC, and explain the mechanisms of Organic Matter
(OM) degradation/sequestration occurring in soil based on possible chemical/morphological
transformations of organic carbon. Most of the performance results are in agreement with the previous
records, but a few contradictions have been observed under diverse experimental conditions.
In general, BAC enhanced the mineralization of carbon and sequestration of heavy metals, and
stabilized labile fraction of OM due to the development of carbonyl, phenolic and aromatic functional
groups on its surface. In addition, aging of biochar resulted in stable N-C=O and amino
groups for the adsorption of nitrogen compounds thus decreasing the potential greenhouse gas
emissions. The study further identifies potential future research gaps in this area.
