Experimental studies of the electronic structure of excess electrons in liquids—archetypal quantum solutes—have been largely restricted to very dilute electron concentrations. We overcame this limitation by applying soft x-ray photoelectron spectroscopy to characterize excess electrons originating from steadily increasing amounts of alkali metals dissolved in refrigerated liquid ammonia microjets. As concentration rises, a narrow peak at ~2 electron volts, corresponding to vertical photodetachment of localized solvated electrons and dielectrons, transforms continuously into a band with a sharp Fermi edge accompanied by a plasmon peak, characteristic of delocalized metallic electrons. Through our experimental approach combined with ab initio calculations of localized electrons and dielectrons, we obtain a clear picture of the energetics and density of states of the ammoniated electrons over the gradual transition from dilute blue electrolytes to concentrated bronze metallic solutions.
Photoelectron
spectroscopy of microjets expanded into vacuum allows
access to orbital energies for solute or solvent molecules in the
liquid phase. Microjets of water, acetonitrile and alcohols have previously
been studied; however, it has been unclear whether jets of low temperature
molecular solvents could be realized. Here we demonstrate a stable
20 μm jet of liquid ammonia (−60 °C) in a vacuum,
which we use to record both valence and core-level band photoelectron
spectra using soft X-ray synchrotron radiation. Significant shifts
from isolated ammonia in the gas-phase are observed, as is the liquid-phase
photoelectron angular anisotropy. Comparisons with spectra of ammonia
in clusters and the solid phase, as well as spectra for water in various
phases potentially reveal how hydrogen bonding is reflected in the
condensed phase electronic structure.
Time-resolved photoelectron spectroscopy (TRPES) in a liquid micro-jet is implemented here to investigate the influence of water on the electronic structure and dynamics of indole, the chromophore of the amino acid tryptophan.
University of Bristol -Explore Bristol Research
General rightsThis document is made available in accordance with publisher policies. Please cite only the published version using the reference above. Abstract: Spectroscopically observing the translational and rotational motion of solute molecules in liquid solutions is typically impeded by their interactions with the solvent, which conceal spectral detail through linewidth broadening. Here we show that unique insights into solute dynamics can be made when using perfluorinated solvents, which interact weakly with solutes and provide a simplified liquid environment that helps to bridge the gap in our understanding of gas and liquid phase dynamics. Specifically, we show that in such solvents, translational and rotational cooling of an energetic CN molecule can be observed directly using ultrafast transient absorption spectroscopy. We observe that translational energy dissipation within these liquids can be modeled through a series of classical collisions, whereas classically simulated rotational energy dissipation is shown to be distinctly faster than experimentally measured. We also observe the onset of rotational hindering from nearby solvent molecules, which arises as the average rotational energy of the solute falls below the effective barrier to rotation induced by the solvent.Introduction:
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