Ultrafast Electron Transfer Dynamics at NH<sub>3</sub>/Cu(111) Interfaces: Determination of the Transient Tunneling Barrier

Stähler, Julia; Meyer, Michael; Kusmierek, D. O.; Bovensiepen, Uwe; Wolf, Martin

doi:10.1021/ja801682u

Cited by 29 publications

(43 citation statements)

References 37 publications

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“…55 The observed decay times are all faster than 500 pssfar too fast to explain residence times of minutes. Extrapolation of the thickness dependent decay times in amorphous ammonia layers to values reported for crystalline ice structures results in a distance of 16 nm between the excess electron and the metal.…”

Section: Comparison Of Experiments and Theorymentioning

confidence: 95%

A Dynamic Landscape from Femtoseconds to Minutes for Excess Electrons at Ice−Metal Interfaces

et al. 2008

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Stabilization of excess electrons is studied at crystalline ice-metal interfaces by femtosecond time-resolved two-photon photoelectron spectroscopy and ab initio calculations. Following optical excitation into delocalized image potential states, electrons localize at pre-existing defects which are located at the ice-vacuum interface. Remarkably, the stabilization of these trapped electrons is monitored continuously from femtoseconds up to minutes. By first principle calculations we identify defect structures, that support excess electrons in front of crystalline ice surfaces, and suggest that the stabilization proceeds through subsequent conformational substates. The excess electron wave functions are efficiently screened from the underlying bulk and explain the long residence times observed in the experiment. Thereby, we shed light on the collective character of the nuclear rearrangement that determines the energetics over all timescales.

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Section: Comparison Of Experiments and Theorymentioning

confidence: 95%

A Dynamic Landscape from Femtoseconds to Minutes for Excess Electrons at Ice−Metal Interfaces

et al. 2008

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“…Here, the electrons always localize at the NH 3 -vacuum interface, as demonstrated by Xe overlayer experiments similar to the ones shown in Figure 16.3 [31]. Assuming that d can be varied systematically and supposing that the resulting transfer probabilities are measured, it would be possible to extract the b and thereby gain information about the tunneling potential.…”

Section: Amorphous Nh 3 On Cu(111)mentioning

confidence: 72%

Electron Dynamics at Polar Molecule–Metal Interfaces: Competition between Localization, Solvation, and Transfer

Stähler

Bovensiepen

Wolf

2010

Dynamics at Solid State Surfaces and Interfaces

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Electron-induced processes and reactions in aqueous systems are of key relevance in diverse fields, ranging from electron transfer and light harvesting in biological systems, photochemistry in the atmosphere, electrochemistry and corrosion, radiation chemistry, and nuclear waste remediation to medical diagnosis and therapy [1][2][3]. These processes usually involve the creation, rearrangement, and transfer of electrons or charged particles in a polar environment. Therefore, solvation and localization of these charges by the reorientation of the surrounding molecular dipoles are key processes that govern the dynamics and reaction rates in aqueous systems or other polar solvents. The solvation reorganization energy, which is associated with the polarization of the solvent environment, determines the energetics and stabilization of charged particles in the solvent. Its magnitude is on the order of several eV [4] and providesfacilitated by thermal fluctuations of the solvent environmentthe driving force for electron transfer in solution. Electron transfer can therefore take place spontaneously at room temperature, as described by Marcus theory [5]. On the other hand, if an excess charge or dipole is suddenly created in a polar solvent (e.g., by photoexcitation), its environment will respond on ultrafast timescales, which are characteristic of the molecular rearrangements of the solvent [6]. In bulk liquid water, for example, the formation dynamics of hydrated electrons involve several intermediate transient species, which can be measured by femtosecond time-resolved IR spectroscopy [7].Solvation processes also play an important role in the context of electron transfer across interfaces between different materials. Such processes are of both fundamental interest and technological significance: The solvation dynamics in a quasi two-dimensional solvent at an interface is expected to differ from isotropic systems due to the reduced dimensionality and the resulting differences in solvent structure and motions [8]. In addition, the electronic coupling at polar molecule-metal interfaces opens a new decay channel for the excited-state population, leading to

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“…This process of electron solvation (step 2) is accompanied by a binding energy gain and the constriction of the excess electron's wave function that is thus becoming increasingly localized. The molecular rearrangement leads to the formation of an interfacial potential well, 40 comparable to small polaron formation, that leads to a decreased wave function overlap of the excess charge with the metal. In other words, the electron is increasingly screened from the substrate.…”

Section: Resultsmentioning

confidence: 99%

“…As shown in ref. 40 and mentioned further above, the solvated electrons reside at the NH 3 -vacuum interface in the case of amorphous ammonia on Cu(111). This occurrence leads to the observation of residence times of the excited electrons that depend exponentially on the ammonia layer thickness (cf.…”

mentioning

confidence: 82%

“…Details on this analysis can be found in ref. 40, however, in the present context, only the resulting exponential dependence is needed to extrapolate to electron residence times on minute timescales as discussed in the following. As mentioned earlier in this section, the increase of excess electron lifetimes that goes along with crystallization may result from (i) an enhancement of the molecular screening and (ii) an increased electron-metal distance due to the morphology change.…”

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Solvation dynamics of surface-trapped electrons at NH3 and D2O crystallites adsorbed on metals: from femtosecond to minute timescales

et al. 2011

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The creation and stabilization of localized, low-energy electrons is investigated in polar molecular environments. We create such excess electrons in excited states in ice and ammonia crystallites adsorbed on metal surfaces and observe their relaxation in real time using time-resolved photoelectron spectroscopy. The observed dynamics proceed up to minute timescales and are therefore slowed down considerably compared to ultrafast excited state relaxation in front of metal surfaces, which proceeds typically on femto-or picosecond time scales. It is the highly efficient wave function constriction of the electrons from the metal that ultimately enables the investigation of the relaxation dynamics over a large range of timescales (up to 17 orders of magnitude). Therefore, it gives novel insight into the solvated electron ground state formation at interfaces. As these long-lived electrons are observed for both, D 2 O and NH 3 crystallites, they appear to be of general character for polar molecule-metal interfaces. Their time-and temperature-dependent relaxation is analyzed for both, crystalline ice and ammonia, and compared using an empirical model that yields insight into the fundamental solvation processes of the respective solvent.

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Ultrafast Electron Transfer Dynamics at NH₃/Cu(111) Interfaces: Determination of the Transient Tunneling Barrier

Cited by 29 publications

References 37 publications

A Dynamic Landscape from Femtoseconds to Minutes for Excess Electrons at Ice−Metal Interfaces

A Dynamic Landscape from Femtoseconds to Minutes for Excess Electrons at Ice−Metal Interfaces

Electron Dynamics at Polar Molecule–Metal Interfaces: Competition between Localization, Solvation, and Transfer

Solvation dynamics of surface-trapped electrons at NH3 and D2O crystallites adsorbed on metals: from femtosecond to minute timescales

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Ultrafast Electron Transfer Dynamics at NH3/Cu(111) Interfaces: Determination of the Transient Tunneling Barrier

Cited by 29 publications

References 37 publications

A Dynamic Landscape from Femtoseconds to Minutes for Excess Electrons at Ice−Metal Interfaces

A Dynamic Landscape from Femtoseconds to Minutes for Excess Electrons at Ice−Metal Interfaces

Electron Dynamics at Polar Molecule–Metal Interfaces: Competition between Localization, Solvation, and Transfer

Solvation dynamics of surface-trapped electrons at NH3 and D2O crystallites adsorbed on metals: from femtosecond to minute timescales

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Ultrafast Electron Transfer Dynamics at NH₃/Cu(111) Interfaces: Determination of the Transient Tunneling Barrier