AI Article Synopsis
- Surface modulation strategies are gaining attention for their ability to enhance material properties like morphology and dispersion, which can also influence electronic functions.
- Researchers have developed a new method using pyrolyzed metal-porphyrin anchored to a nitrogen-doped carbon layer to create an effective electromagnetic wave absorber that overcomes limitations found in existing models.
- The new material (sM(N)@NC) demonstrates impressive performance with a strong absorption bandwidth and exceptional reflection loss, showcasing the potential for precise design of EMW absorbers using single metal sites.
Article Abstract
Surface modulation strategies have spurred great interest with regard to regulating the morphology, dispersion and flexible processability of materials. Unsurprisingly, customized modulation of surfaces is primed to offer a route to control their electronic functions. To regulate electromagnetic wave (EMW) absorption applications by surface engineering is an unmet challenge. Thanks to pyrolyzing surface-anchored metal-porphyrin, here we report on the surface modulation of four-nitrogen atoms-confined single metal site on a nitrogen-doped carbon layer (sM(N)@NC, M = Ni, Co, Cu, Ni/Cu) (sM=single metal; NC= nitrogen-doped carbon layer) that registers electromagnetic wave absorption. Surface-anchored metal-porphyrins are afforded by attaching them onto the polypyrrole surface via a prototypical click reaction. Further, sM(N)@NC is experimentally found to elicit an identical dipole polarization loss mechanism, overcoming the handicaps of conductivity loss, defects, and interfacial polarization loss among the current EMW absorber models. Importantly, sM(N)@NC is found to exhibit an effective absorption bandwidth of 6.44 and reflection loss of -51.7 dB, preceding state-of-the-art carbon-based EMW absorbers. This study introduces a surface modulation strategy to design EMW absorbers based on single metal sites that enable fine-tunable and controlled absorption mechanism with atomistic precision.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11494010 | PMC |
| http://dx.doi.org/10.1038/s41467-024-53465-1 | DOI Listing |
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