Excited state dynamics of Zn–salophen complexes

Abstract: Zn–salophen complexes are a promising class of fluorescent chemosensors for nucleotides and nucleic acids. We have investigated, by means of steady state UV–Vis, ultrafast transient absorption, fluorescence emission and time dependent density functional theory (TD-DFT) the behavior of the excited states of a salicylidene tetradentate Schiff base (Sal), its Zn(II) coordination compound (Zn–Sal) and the effect of the interaction between Zn–Sal and adenosine diphosphate (ADP). TD-DFT shows that the deactivation o… Show more

“…Although expanded-porphyrin macrocycles are characterized with favorable cavities for adsorption, their synthetic feasibility and kinetics are challenging and thus unfavorable toward actinyl complexation. 29−34 Compared to the macrocyclic ligands, acyclic ligands have been widely used in molecular recognition and self-assembly of main group elements, 35,36 and they can also be utilized for chemical bonding and complexation with actinyl cations. 27,37 Specifically, pyrrol-2-ylphenyleneamine was earlier reported for its self-assembly and coordination with Zn(II) ions.…”

“…Ligands with mixed nitrogen and oxygen (as hard and soft) donor atoms such as oxygen-substituted expanded porphyrin, acyclic salophen and salen -type ligands were investigated to be favorable toward the relative softness of the hard actinyl acceptors. Although expanded-porphyrin macrocycles are characterized with favorable cavities for adsorption, their synthetic feasibility and kinetics are challenging and thus unfavorable toward actinyl complexation. − Compared to the macrocyclic ligands, acyclic ligands have been widely used in molecular recognition and self-assembly of main group elements, , and they can also be utilized for chemical bonding and complexation with actinyl cations. , Specifically, pyrrol-2-ylphenyleneamine was earlier reported for its self-assembly and coordination with Zn­(II) ions . Recently, the benzyl ester derivative of the ethyl ester bis­(pyrrole)­phenylenediamine, also called pyrrophen, was tailor-made for the purpose of molecular recognition of UO 2 2+ forming a 1:1 complex .…”

Periodic Trends in the Stabilization of Actinyls in Their Higher Oxidation States Using Pyrrophen Ligands

“…Although expanded-porphyrin macrocycles are characterized with favorable cavities for adsorption, their synthetic feasibility and kinetics are challenging and thus unfavorable toward actinyl complexation. 29−34 Compared to the macrocyclic ligands, acyclic ligands have been widely used in molecular recognition and self-assembly of main group elements, 35,36 and they can also be utilized for chemical bonding and complexation with actinyl cations. 27,37 Specifically, pyrrol-2-ylphenyleneamine was earlier reported for its self-assembly and coordination with Zn(II) ions.…”

“…Ligands with mixed nitrogen and oxygen (as hard and soft) donor atoms such as oxygen-substituted expanded porphyrin, acyclic salophen and salen -type ligands were investigated to be favorable toward the relative softness of the hard actinyl acceptors. Although expanded-porphyrin macrocycles are characterized with favorable cavities for adsorption, their synthetic feasibility and kinetics are challenging and thus unfavorable toward actinyl complexation. − Compared to the macrocyclic ligands, acyclic ligands have been widely used in molecular recognition and self-assembly of main group elements, , and they can also be utilized for chemical bonding and complexation with actinyl cations. , Specifically, pyrrol-2-ylphenyleneamine was earlier reported for its self-assembly and coordination with Zn­(II) ions . Recently, the benzyl ester derivative of the ethyl ester bis­(pyrrole)­phenylenediamine, also called pyrrophen, was tailor-made for the purpose of molecular recognition of UO 2 2+ forming a 1:1 complex .…”

Periodic Trends in the Stabilization of Actinyls in Their Higher Oxidation States Using Pyrrophen Ligands

The crystal structures of Imine-Enamine ‘tautomerism’ in solid state and “turn on” sensing for Zn2+: spectroscopy, DFT and cell imaging studies