Biomass waste-derived porous carbons (BWDPCs) are a class of complex materials that are widely used in sustainable waste management and carbon capture. However, their diverse textural properties, the presence of various functional groups, and the varied temperatures and pressures to which they are subjected during CO 2 adsorption make it challenging to understand the underlying mechanism of CO 2 adsorption. Here, we compiled a data set including 527 data points collected from peer-reviewed publications and applied machine learning to systematically map CO 2 adsorption as a function of the textural and compositional properties of BWDPCs and adsorption parameters. Various tree-based models were devised, where the gradient boosting decision trees (GBDTs) had the best predictive performance with R 2 of 0.98 and 0.84 on the training and test data, respectively. Further, the BWDPCs in the compiled data set were classified into regular porous carbons (RPCs) and heteroatom-doped porous carbons (HDPCs), where again the GBDT model had R 2 of 0.99 and 0.98 on the training and 0.86 and 0.79 on the test data for the RPCs and HDPCs, respectively. Feature importance revealed the significance of adsorption parameters, textural properties, and compositional properties in the order of precedence for BWDPC-based CO 2 adsorption, effectively guiding the synthesis of porous carbons for CO 2 adsorption applications.
Biochar application
is a promising strategy for the remediation
of contaminated soil, while ensuring sustainable waste management.
Biochar remediation of heavy metal (HM)-contaminated soil primarily
depends on the properties of the soil, biochar, and HM. The optimum
conditions for HM immobilization in biochar-amended soils are site-specific
and vary among studies. Therefore, a generalized approach to predict
HM immobilization efficiency in biochar-amended soils is required.
This study employs machine learning (ML) approaches to predict the
HM immobilization efficiency of biochar in biochar-amended soils.
The nitrogen content in the biochar (0.3–25.9%) and biochar
application rate (0.5–10%) were the two most significant features
affecting HM immobilization. Causal analysis showed that the empirical
categories for HM immobilization efficiency, in the order of importance,
were biochar properties > experimental conditions > soil properties
> HM properties. Therefore, this study presents new insights into
the effects of biochar properties and soil properties on HM immobilization.
This approach can help determine the optimum conditions for enhanced
HM immobilization in biochar-amended soils.
The COVID-19 pandemic is exacerbating plastic pollution. A shift in waste management practices is thus urgently needed to close the plastic loop, requiring governments, researchers and industries working towards intelligent design and sustainable upcycling.
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