List references from the University of Geneva Physical Chemistry reference database

Thiolate-protected gold clusters are promising candidates for imaging applications due to their interesting, size-dependent properties. Their high stability and the ability to functionalize the clusters with biocompatible ligands render the clusters interesting for various imaging techniques such as fluorescence microscopy or second-harmonic generation microscopy. The latter nonlinear optical effect has not yet been observed on this type of ultrasmall nanoparticle. We hereby present second- and third-harmonic generation and multiphoton fluorescence of two thiolate-protected gold clusters: Au₂₅(SCH ₂CH₂Ph)₁₈ and Au₃₈(SCH₂CH₂Ph)₂₄. At a fundamental wavelength of 800 nm, the Au₃₈(SCH₂CH₂Ph)₂₄ cluster is active. In contrast, Au₂₅(SCH₂CH₂Ph)_18Âdoes not yield significant SHG signal. We ascribe this to the center of inversion in the Au₂₅ cluster. Measurements on chiral Au₂₅(capt)₁₈ (capt: captopril) gave an SHG response, supporting this interpretation. We also observed third-harmonic generation at a fundamental wavelength of 1200 nm. At 800 and 1100 nm, the clusters decompose after short illumination time but are stable at illumination at 1200 nm. This may be exploited in combined deep tissue imaging and photothermal heating for theranostics applications

The Au₁₀₂(p-MBA)₄₄ cluster (p-MBA: para-mercaptobenzoic acid) is observed as a chiral compound comprised of achiral components in its single-crystal structure. So far the enantiomers observed in the crystal structure are not isolated, nor is the circular dichroism spectrum known. A chiral phase transfer method is presented which allows partial resolution of the enantiomers by the use of a chiral ammonium bromide, (âˆ’)-1R,2S-N-dodecyl-N-methylephedrinium bromide ((âˆ’)-DMEBr). At sufficiently low concentration of (âˆ’)-DMEBr, the phase transfer from water to chloroform is incomplete. Both the aqueous and organic phases show optical activity of near mirror image relationship. Differences in the spectra are ascribed to the formation of diastereomeric salts. At high concentrations of (âˆ’)-DMEBr, full phase transfer is observed. The organic phase, however, still displays optical activity. We assume that one of the diastereomers has very strong optical activity, which overrules the cancelation of the spectra with opposite sign. Comparison with computations further corroborates the experimental data and allows a provisional assignment of handedness of each fraction.

Nonlinear Optical Properties of Thiolate-Protected Gold Clusters S. Knoppe, M. Vanbel, S. Van Cleuvenbergen, L. Vanpraet, T. Bürgi and T. Verbiest The Journal of Physical Chemistry C, 119 (11) (2015), p6221-6226 DOI:10.1021/acs.jpcc.5b01475 \| unige:94106 \| Abstract \| Article HTML \| Article PDF
Thiolate-protected gold clusters are promising candidates for imaging applications due to their interesting, size-dependent properties. Their high stability and the ability to functionalize the clusters with biocompatible ligands render the clusters interesting for various imaging techniques such as fluorescence microscopy or second-harmonic generation microscopy. The latter nonlinear optical effect has not yet been observed on this type of ultrasmall nanoparticle. We hereby present second- and third-harmonic generation and multiphoton fluorescence of two thiolate-protected gold clusters: Au₂₅(SCH ₂CH₂Ph)₁₈ and Au₃₈(SCH₂CH₂Ph)₂₄. At a fundamental wavelength of 800 nm, the Au₃₈(SCH₂CH₂Ph)₂₄ cluster is active. In contrast, Au₂₅(SCH₂CH₂Ph)_18Âdoes not yield significant SHG signal. We ascribe this to the center of inversion in the Au₂₅ cluster. Measurements on chiral Au₂₅(capt)₁₈ (capt: captopril) gave an SHG response, supporting this interpretation. We also observed third-harmonic generation at a fundamental wavelength of 1200 nm. At 800 and 1100 nm, the clusters decompose after short illumination time but are stable at illumination at 1200 nm. This may be exploited in combined deep tissue imaging and photothermal heating for theranostics applications


Chiral Phase Transfer and Enantioenrichment of Thiolate-Protected Au ₁₀₂ Clusters S. Knoppe, O.A. Wong, S. Malola, H. Häkkinen, T. Bürgi, T. Verbiest and C.J. Ackerson Journal of the American Chemical Society, 136 (11) (2014), p4129-4132 DOI:10.1021/ja500809p \| unige:94110 \| Abstract \| Article HTML \| Article PDF \| Supporting Info
The Au₁₀₂(p-MBA)₄₄ cluster (p-MBA: para-mercaptobenzoic acid) is observed as a chiral compound comprised of achiral components in its single-crystal structure. So far the enantiomers observed in the crystal structure are not isolated, nor is the circular dichroism spectrum known. A chiral phase transfer method is presented which allows partial resolution of the enantiomers by the use of a chiral ammonium bromide, (âˆ’)-1R,2S-N-dodecyl-N-methylephedrinium bromide ((âˆ’)-DMEBr). At sufficiently low concentration of (âˆ’)-DMEBr, the phase transfer from water to chloroform is incomplete. Both the aqueous and organic phases show optical activity of near mirror image relationship. Differences in the spectra are ascribed to the formation of diastereomeric salts. At high concentrations of (âˆ’)-DMEBr, full phase transfer is observed. The organic phase, however, still displays optical activity. We assume that one of the diastereomers has very strong optical activity, which overrules the cancelation of the spectra with opposite sign. Comparison with computations further corroborates the experimental data and allows a provisional assignment of handedness of each fraction.

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