AI Article Synopsis
- Researchers demonstrated that electrochemical doping can effectively manipulate charges in molecules, specifically β-carotene, when they are enclosed within single-wall carbon nanotubes (SWCNTs).
- The study analyzed how the Raman spectra of both β-carotene and SWCNTs responded differently to changes in electrochemical potentials, revealing distinct doping behaviors.
- Despite successfully extracting electrons from the encapsulated β-carotene, the findings suggested that manipulating charges is challenging due to significant on-site Coulomb repulsion affecting the molecules inside the nanotubes.
Article Abstract
We report clear experimental evidence for the charge manipulation of molecules encapsulated inside single-wall carbon nanotubes (SWCNTs) using electrochemical doping techniques. We encapsulated β-carotene (Car) inside SWCNTs and clarified electrochemical doping characteristics of their Raman spectra. C=C streching modes of encapsulated Car and a G band of SWCNTs showed clearly different doping behaviors as the electrochemical potentials were shifted. Electron extraction from encapsulated Car was clearly achieved. However, electrochemical characteristics of Car inside SWCNTs and doping mechanisms elucidated by calculations based on density-functional theory indicate the difficulty of charge manipulation of molecules inside SWCNTs due to the presence of strong on-site Coulomb repulsion energy at the molecules.
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| http://dx.doi.org/10.1103/PhysRevLett.110.086801 | DOI Listing |
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