AI Article Synopsis
- ALC-μSR spectroscopy was utilized to investigate radicals formed by adding muonium to the discotic liquid crystal HHTT.
- The addition resulted in a cyclohexadienyl radical, confirmed through comparison of hyperfine coupling constants with DFT calculations.
- The study revealed that in isotropic and hexagonal phases, electron spin relaxation occurs much faster than in helical and crystalline phases, influenced by temperature and motion within the HHTT columns, which may affect the viability of DLCs for spin-based technologies.
Article Abstract
Avoided level crossing muon spin resonance (ALC-μSR) spectroscopy was used to study radicals produced by the addition of the light hydrogen isotope muonium (Mu) to the discotic liquid crystal (DLC) 2,3,6,7,10,11-hexahexylthiotriphenylene (HHTT). Mu adds to the secondary carbon atoms of HHTT to produce a substituted cyclohexadienyl radical, whose identity was confirmed by comparing the measured hyperfine coupling constants with values obtained from DFT calculations. ALC-μSR spectra were obtained in the isotropic (I), hexagonal columnar (Col(h)), helical (H), and crystalline (Cr) phases. In the I and Col(h) phases the radicals, which are incorporated within the stacks of HHTT molecules as isolated paramagnetic defects, undergo extremely rapid electron spin relaxation, on the order of a hundredfold faster than in the H or Cr phases. The electron spin relaxation rate increases significantly with increasing temperature and appears to be caused by the liquidlike motion within the columns, which modulates the overlap between the π system of the radical and the π systems of the neighboring HHTT molecules, and hence, the hyperfine coupling constants. Rapid electron spin relaxation should occur for any π radical incorporated within the columns of a DLC, which may limit the utility of DLCs for future spin-based technologies.
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| http://dx.doi.org/10.1103/PhysRevE.87.012504 | DOI Listing |
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