A chromatography-free total synthesis of a ferrocene-containing dendrimer exhibiting the property of recognizing 9,10-diphenylanthracene

Abstract: Efficient chromatography-free synthesis of a new example of an aromatic dendrimer bearing nine ferrocene residues and its application in the detection of 9,10-diphenylanthracene are reported.

“…It is noteworthy that our previous studies ( 1 H NMR, 1 H DOSY NMR, cold‐spray ESI‐MS and emission spectra experiments) revealed that Fc‐1 can interact with aromatic species by means of dynamic π‐π stacking‐like non‐covalent forces [35] . This observation was further supported by our works on 1,3,5‐triphenylbenzene containing dendritic molecule [46] . Furthermore, our studies on the interactions between Fc‐2 and pyrene as the representative aromatic molecule revealed that this interaction can be characterized by the similar apparent association constant ( K app ) value as for the pyrene‐ Fc‐1 system reported previously; [35] The estimated K app value for pyrene‐ Fc‐2 system equals to 5.1(2) ⋅ 10 2 M −1 (Gibbs free energy (Δ G ) value is −15.5 kJ ⋅ mol −1 ; see data and calculation details in Section S6, Supporting Information).…”

“…[35] This observation was further supported by our works on 1,3,5triphenylbenzene containing dendritic molecule. [46] Furthermore, our studies on the interactions between Fc-2 and pyrene as the representative aromatic molecule revealed that this interaction can be characterized by the similar apparent association constant (K app ) value as for the pyrene-Fc-1 system reported previously; [35] The estimated K app value for pyrene-Fc-2 system equals to 5.1(2) • 10 2 M À 1 (Gibbs free energy (ΔG) value is À 15.5 kJ • mol À 1 ; see data and calculation details in Section S6, Supporting Information). For comparison, for the pyrene-Fc-1 system, K app and ΔG equal to 4.0(3) • 10 2 M À 1 and À 14.9 kJ • mol À 1 , respectively.…”

Electrochemical Recognition of Aromatic Species with Ferrocenylated 1,3,5‐Triazine‐ or 1,3,5‐Triphenylbenzene‐Containing Highly Organized Molecules

“…It is noteworthy that our previous studies ( 1 H NMR, 1 H DOSY NMR, cold‐spray ESI‐MS and emission spectra experiments) revealed that Fc‐1 can interact with aromatic species by means of dynamic π‐π stacking‐like non‐covalent forces [35] . This observation was further supported by our works on 1,3,5‐triphenylbenzene containing dendritic molecule [46] . Furthermore, our studies on the interactions between Fc‐2 and pyrene as the representative aromatic molecule revealed that this interaction can be characterized by the similar apparent association constant ( K app ) value as for the pyrene‐ Fc‐1 system reported previously; [35] The estimated K app value for pyrene‐ Fc‐2 system equals to 5.1(2) ⋅ 10 2 M −1 (Gibbs free energy (Δ G ) value is −15.5 kJ ⋅ mol −1 ; see data and calculation details in Section S6, Supporting Information).…”

“…[35] This observation was further supported by our works on 1,3,5triphenylbenzene containing dendritic molecule. [46] Furthermore, our studies on the interactions between Fc-2 and pyrene as the representative aromatic molecule revealed that this interaction can be characterized by the similar apparent association constant (K app ) value as for the pyrene-Fc-1 system reported previously; [35] The estimated K app value for pyrene-Fc-2 system equals to 5.1(2) • 10 2 M À 1 (Gibbs free energy (ΔG) value is À 15.5 kJ • mol À 1 ; see data and calculation details in Section S6, Supporting Information). For comparison, for the pyrene-Fc-1 system, K app and ΔG equal to 4.0(3) • 10 2 M À 1 and À 14.9 kJ • mol À 1 , respectively.…”

Electrochemical Recognition of Aromatic Species with Ferrocenylated 1,3,5‐Triazine‐ or 1,3,5‐Triphenylbenzene‐Containing Highly Organized Molecules

Ferrocenylated 1,3,5-triphenylbenzenes for the electrochemical detection of various cations or anions

Fast, solvent-free synthesis of ferrocene-containing organic cages via dynamic covalent chemistry in the solid state