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Beilstein J. Nanotechnol. 2022, 13, 1201–1219, doi:10.3762/bjnano.13.100
Figure 1: Self-assembly monolayer of ʟ-phenylalanine as a selector layer for the QCM chiral sensor [26].
Figure 2: Poly(EDOT-OH) layers with different morphologies for chiral detection in the QCM system. Redrawn fr...
Figure 3: The formation of molecular imprinted polymers for chiral recognition [39].
Figure 4: The chiral selector layer fabricated by the deposition of molecular imprinted polymer nanoparticles...
Figure 5: Chiral recognition of cyclodextrins by cavity size and linker length in the QCM system. The models ...
Figure 6: The chiral calix[4]arene layer as a selector for enantioselective adsorption of ascorbic acid in th...
Figure 7: The porphyrin diad layer as a chiral selector for detection of chiral limonene in the QCM system [88].
Figure 8: The UiO-MOF-derived QCM sensor for efficient discrimination of cysteine enantiomers in the QCM syst...
Figure 9: The comparison of homochiral and achiral MOF structures for chiral recognition in the QCM system. R...
Figure 10: The formation of a chiral ceramic layer for chiral recognition in the QCM system [121].
Figure 11: The chiral recognition by a bare metal layer in the QCM system. Redrawn from [144].
Figure 12: The chiral recognition on the metal layer induced by magnetic field in the QCM system [145].