An understanding of the photoisomerization mechanism of molecules bound to a metal surface at the molecular scale is required for designing photoswitches at surfaces. It has remained a challenge to correlate the surface structure and isomerization of photoswitches at ambient conditions. Herein, the photoisomerization of a self-assembled monolayer of azobenzene-thiol molecules on a Au surface was investigated using scanning tunneling microscopy and tip-enhanced Raman spectroscopy. The unique signature of the cis isomer at 1525 cm observed in tip-enhanced Raman spectra was clearly distinct from the trans isomer. Furthermore, tip-enhanced Raman images of azobenzene thiols after ultraviolet and blue light irradiation are shown with nanoscale spatial resolution, demonstrating a reversible conformational change. Interestingly, the cis isomers of azobenzene-thiol molecules were preferentially observed at Au grain edges, which is confirmed by density functional theory.
Photoswitches can be employed for various purposes, with the half-life being a crucial parameter to optimize for the desired application. The switching of a photochromic hydrazone functionalized with a C6 alkyl thiolate spacer (C6 HAT) was characterized on a number of metal surfaces. C6 HAT exhibits a half-life of 789 years in solution. Tip-enhanced Raman spectroscopy (TERS) was used to study the photoisomerization of the C6 HAT self-assembled monolayers (SAM) on Au, Ag and Cu surfaces. The unique spectroscopic signature of the E isomer at 1580 and 1730 cm-1 in TER spectra allowed for its discrimination from the Z isomer. It was found that C6 HAT switches on Au and Cu surfaces when irradiated with 415 nm, however it cannot isomerize on Ag surfaces, unless higher energy light is used. Based on this finding, and supported by density functional theory calculations, we propose a substrate-mediated photoisomerization mechanism to explain the behavior of C6 HAT on these different metal surfaces. This insight into the hydrazone's switching mechanism on metal surfaces will contribute to the further exploitation of this new family photochromic compounds on metal surfaces. Finally, although we found that the thermal isomerization rate of C6 HAT drastically increases on metal surfaces, the thermal half-life is still 6.9 days on gold, which is longer than the majority of azobenzene-based systems. Figure 1. A. Light induced Z/E isomerization of C6 HAT; B. UV-vis spectra of C6 HAT in toluene (1x 10-5 M) before (solid line) and after irradiation with 410 nm light (dashed line), followed by irradiation with 340 nm light (dotted line).
Metal–organic coordination
structures at interfaces play
an essential role in many biological and chemical systems. Understanding
the molecular specificity, orientation, and spatial distribution of
the coordination complexes at the nanometer scale is of great importance
for effective molecular engineering of nanostructures and fabrication
of functional devices with controllable properties. However, fundamental
properties of such coordination systems are still rarely studied directly.
In this work, we present a spectroscopic approach on the basis of
tip-enhanced Raman spectroscopy (TERS) to investigate cobalt(II) tetraphenyl-porphyrine
coordination species on the scale of a single molecule under ambient
conditions. Coordination species anchored on gold surfaces modified
with pyridine thiol self-assembled monolayers can be spectroscopically
distinguished and mapped with ca. 2 nm resolution.
In addition, in combination with density functional theory simulations,
the adsorption configuration and molecular orientation of the coordination
complexes are also revealed using TERS imaging.
In
this work we prepare Langmuir–Blodgett monolayers with
a trifunctional amphiphilic anthraphane monomer. Upon spreading at
the air/water interface, the monomers self-assemble into 1 nm-thin
monolayer islands, which are highly fluorescent and can be visualized
by the naked eye upon excitation. In situ fluorescence
spectroscopy indicates that in the monolayers, all the anthracene
units of the monomers are stacked face-to-face forming excimer pairs,
whereas at the edges of the monolayers, free anthracenes are present
acting as edge groups. Irradiation of the monolayer triggers [4 +
4]-cycloadditions among the excimer pairs, effectively resulting in
a two-dimensional (2D) polymerization. The polymerization reaction
also completely quenches the fluorescence, allowing to draw patterns
on the monomer monolayers. More interestingly, after transferring
the monomer monolayer on a solid substrate, by employing masks or
the laser of a confocal scanning microscope, it is possible to arbitrarily
select the parts of the monolayer that one wants to polymerize. The
unpolymerized regions can then be washed away from the substrate,
leaving 2D macromolecular monolayer objects of the desired shape.
This photolithographic process employs 2D polymerizations and affords
1 nm-thin coatings.
The reaction between MO and NaBH4 catalyzed by Ag NPs has been studied. Ag NPs catalyzed the reduction of MO rapidly, while adding CTAB into the solution caused the regeneration of MO. Thus, reversible catalysis for the reaction between MO and NaBH4 by Ag NPs was discovered for the first time.
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