Surface-enhanced, multi-dimensional attenuated total reflectance spectroscopy

Kaech

Hamm

2017

Structural Dynamics

Self Cite

Ultrafast vibrational dynamics of small molecules on platinum (Pt) layers in water are investigated using 2D attenuated total reflectance IR spectroscopy. Isotope combinations of carbon monoxide and cyanide are used to elucidate inter-adsorbate and substrate-adsorbate interactions. Despite observed cross-peaks in the CO spectra, we conclude that the molecules are not vibrationally coupled. Rather, strong substrate-adsorbate interactions evoke rapid (∼2 ps) vibrational relaxation from the adsorbate into the Pt layer, leading to thermal cross-peaks. In the case of CN, vibrational relaxation is significantly slower (∼10 ps) and dominated by adsorbate-solvent interactions, while the coupling to the substrate is negligible.

Section: Methodsmentioning

confidence: 99%

Molecule-specific interactions of diatomic adsorbates at metal-liquid interfaces

Kaech

Hamm

2017

Structural Dynamics

Self Cite

“…[24][25][26] Under these circumstances, immobilization of the sample at the interface allows obtaining surface-sensitive signals from solid-liquid interfaces. With this approach, we have recently investigated the ultrafast vibrational dynamics of surface-bound carbon monoxide 17,27 and cyanide 28 as well as self-assembled organic monolayers under various conditions 18,19,29,30 . Figure 1.…”

mentioning

confidence: 99%

“…20 Since we however do not observe any direct cross peak, we assume that Eq. 3 overestimates the coupling, which is counter-balanced by the fact that cross-relaxation can proceed to more than one coupling partner on the surface (the model Despite significant efforts reported in literature 30,[47][48][49] , intermolecular couplings of surface-bound molecules have only rarely been observed 38 , and the estimates given above help to understand why that is so. In the present case, we can observe cross peaks with good signal-to-noise ratio, but this is since we have the very strong transition dipole of the symmetric stretch vibration of a metal-carbonyl together with (presumably) a close to optimal packing on the surface.…”

mentioning

confidence: 99%

Ultrafast Vibrational Energy Transfer in Catalytic Monolayers at Solid–Liquid Interfaces

Frei

Alberto

et al. 2017

J. Phys. Chem. Lett.

Self Cite

We investigate the ultrafast vibrational dynamics of monolayers from adsorbed rhenium-carbonyl CO-reduction catalysts on a semiconductor surface (indium-tin-oxide (ITO)) with ultrafast two-dimensional attenuated total reflection infrared (2D ATR IR) spectroscopy. The complexes are partially equipped with isotope-labeled (C) carbonyl ligands to generate two spectroscopically distinguishable forms of the molecules. Ultrafast vibrational energy transfer between the molecules is observed via the temporal evolution of cross-peaks between their symmetric carbonyl stretching vibrations. These contributions appear with time constant of 70 and 90 ps for downhill and uphill energy transfer, respectively. The energy transfer is thus markedly slower than any of the other intramolecular dynamics. From the transfer rate, an intermolecular distance of ∼4-5 Å can be estimated, close to the van der Waals distance of the molecular head groups. The present paper presents an important cornerstone for a better understanding of intermolecular coupling mechanisms of molecules on surfaces and explains the absence of similar features in earlier studies.

“…Specifically, we use 2D ATR IR spectroscopy, which has been introduced recently as a new and very flexible technique for surface vibrational characterization of adsorbates in different environments. [35][36][37] The information content in 2D ATR IR spectra is analogous to that of "classic" 2D IR spectroscopy in transmission geometry 33,34 , but rather exploits evanescent waves at the interface of an ATR element to excite and probe the sample.…”

mentioning

confidence: 99%

Plasmonic Substrates Do Not Promote Vibrational Energy Transfer at Solid–Liquid Interfaces

Sévery

Tilley

et al. 2017

J. Phys. Chem. Lett.

Self Cite

Intermolecular vibrational energy transfer in monolayers of isotopically mixed rhenium carbonyl complexes at solid-liquid interfaces is investigated with the help of ultrafast 2D Attenuated Total Reflectance Infrared (2D ATR IR) spectroscopy in dependence of plasmonic surface enhancement effects. Dielectric and plasmonic materials are used to demonstrate that plasmonic effects have no impact on the vibrational energy transfer rate in a regime of moderate IR surface enhancement (enhancement factors up to ca. 30). This result can be explained with the common image-dipole picture. The vibrational energy transfer rate thus can be used as a direct observable to determine intermolecular distances on surfaces, regardless of their plasmonic properties.