| Summary: | Carbon nanomaterials are widely studied and applied nowadays, with annual production increasing. After entering the environment, the complete degradation of these carbon nanomaterials by microorganisms is proposed as an effective approach for detoxification and remediation. In this study, we evaluated the degradation of pristine multiwalled carbon nanotubes (p-MWCNTs) and oxidized multiwalled carbon nanotubes (o-MWCNTs) by the white rot fungus <i>Phanerochaete chrysosporium</i>, which is a powerful decomposer in the carbon cycle and environmental remediation. Both p-MWCNTs and o-MWCNTs were partially oxidized by <i>P. chrysosporium</i> as indicated by the addition of oxygen atoms to the carbon skeleton in the forms of C=O and O−H bonds. The fungal oxidation led to the shortening of MWCNTs, where precipitated o-MWCNTs showed more short tubes. During the transformation, the defects on the tubes became detached from the carbon skeleton, resulting in decreases of the <i>I</i><sub>D</sub>/<i>I</i><sub>G</sub> (intensity of D-band/ intensity of G-band) values in Raman spectra. The transformation mechanism was attributed to the enzymatic degradation by laccase and manganese peroxidase excreted by <i>P. chrysosporium</i>. The results collectively indicated that MWCNTs could be transformed by <i>P. chrysosporium</i>, but complete degradation could not be achieved in a short time period. The implications on the environmental risks of carbon nanomaterials are discussed.
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