Spatially Resolved Vibrational Energy Transfer in Molecular Monolayers

Carter, Jeffrey A.; Wang, Zhaohui; Dlott, Dana D.

doi:10.1021/jp800278c

Cited by 30 publications

(51 citation statements)

References 48 publications

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“…An important driving factor in this growing interest is the development of experimental capabilities that greatly improve on the ability to gauge temperatures (and "effective" temperatures in nonequilibrium systems) with high spatial and thermal resolutions (29-43) and to infer from such measurement the underlying heat transport processes. In particular, vibrational energy transport/ heat conduction in molecular layers and junctions has recently been characterized using different probes (6,19,(44)(45)(46)(47)(48)(49)(50)(51)(52).The interplay between charge and energy (electronic and nuclear) transport (53-60) is of particular interest as it pertains to the performance of energy-conversion devices, such as thermoelectric, photovoltaic, and electromechanical devices. In particular, the thermoelectric response of molecular junctions, mostly focusing on the junction linear response as reflected by its Seebeck coefficient, has been recently observed (61-65) and theoretically analyzed (2,20,64,(66)(67)(68)(69)(70)(71)(72)(73)(74)(75)(76)(77).…”

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confidence: 99%

Electron transfer across a thermal gradient

Craven

Nitzan

2016

Proc. Natl. Acad. Sci. U.S.A.

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Charge transfer is a fundamental process that underlies a multitude of phenomena in chemistry and biology. Recent advances in observing and manipulating charge and heat transport at the nanoscale, and recently developed techniques for monitoring temperature at high temporal and spatial resolution, imply the need for considering electron transfer across thermal gradients. Here, a theory is developed for the rate of electron transfer and the associated heat transport between donor-acceptor pairs located at sites of different temperatures. To this end, through application of a generalized multidimensional transition state theory, the traditional Arrhenius picture of activation energy as a single point on a free energy surface is replaced with a bithermal property that is derived from statistical weighting over all configurations where the reactant and product states are equienergetic. The flow of energy associated with the electron transfer process is also examined, leading to relations between the rate of heat exchange among the donor and acceptor sites as functions of the temperature difference and the electronic driving bias. In particular, we find that an open electron transfer channel contributes to enhanced heat transport between sites even when they are in electronic equilibrium. The presented results provide a unified theory for charge transport and the associated heat conduction between sites at different temperatures. T he study of electronic transport in molecular nanojunctions naturally involves consideration of inelastic transport, where the transporting electron can exchange energy with underlying nuclear motions (1, 2). Such studies have been motivated by the use of inelastic tunneling spectroscopy, and more recently Raman spectroscopy, as diagnostic tools on one hand, and by considerations of junction stability on the other. In parallel, there has been an increasing interest in vibrational heat transport in nanostructures and their interfaces with bulk substrates (3-11) focusing on structure-transport correlations (12-15), moleculesubstrate coupling (16-18), ballistic and diffusive transport processes (11,19), and rectification (20-22). More recently, noise (23-26), nonlinear response (e.g., negative differential heat conductance), and control by external stimuli (27, 28) have been examined. An important driving factor in this growing interest is the development of experimental capabilities that greatly improve on the ability to gauge temperatures (and "effective" temperatures in nonequilibrium systems) with high spatial and thermal resolutions (29-43) and to infer from such measurement the underlying heat transport processes. In particular, vibrational energy transport/ heat conduction in molecular layers and junctions has recently been characterized using different probes (6,19,(44)(45)(46)(47)(48)(49)(50)(51)(52).The interplay between charge and energy (electronic and nuclear) transport (53-60) is of particular interest as it pertains to the performance of energy-conversion devices, such as therm...

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confidence: 99%

Electron transfer across a thermal gradient

Craven

Nitzan

2016

Proc. Natl. Acad. Sci. U.S.A.

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“…Figure 6(a) shows nonresonance-suppressed s (NO 2 ) spectra as a function of delay. We analyzed those spectra using the method of moments, where the first three moments M (0) (t), M (1) (t) and M (2) …”

Section: B Flash-heating Reflectivity Transientsmentioning

confidence: 99%

“…9(a), creating disorder in the nitro group ensemble. The SFG signal is proportional to the square of a second-order susceptibility v (2) , which itself is the ensemble average of individual molecular hyperpolarizabilities. Disorder reduces this average, thereby reducing s (NO 2 ) SFG signals.…”

Section: B Nitrobenzenethiolate Flash-heatingmentioning

confidence: 99%

“…5 We showed it was possible to use SFG to probe hot electron-and phonon-excited vibrations at multiple locations on the adsorbate molecules, 2 and it was shown that the hot electrons excited atomic groups most effectively if they were no farther than 4-5 carbon atoms away from the surface. 5 Flash-heating of Au surfaces by short pulses of light has been studied extensively over the past 25 years using transient reflectance probes.…”

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confidence: 99%

“…1,5 Some of the measurements here were made using 800 nm flash-heating pulses to produce DT ¼ 35 K as used in previous works. [1][2][3][4][5] In addition, we used 400 nm (blue) pulses, which are more strongly absorbed by Au, to make the same DT ¼ 35 K and also much larger-amplitude T-jumps where DT ¼ 175 K.…”

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confidence: 99%

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Probing of molecular adsorbates on Au surfaces with large-amplitude temperature jumps

Berg

Lagutchev

Dlott

2013

Journal of Applied Physics

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Methods are described to probe vibrational transitions of molecules adsorbed on Au films subjected to calibrated ultrafast large-amplitude temperature jumps (T-jumps). The probe technique, vibrational sum-frequency generation (SFG), can monitor vibrations localized on specific parts of adsorbate molecules in the form of self-assembled monolayers (SAMs). Substrates had a thin Cr adhesion layer and an Au film that could withstand millions of T-jumps without laser damage of film or adsorbate. The substrate flash-heating process was characterized using ultrafast reflectance measurements. Reflectance transients induced by both 800 nm or 400 nm femtosecond pulses had overshoot-decay-plateau structures. The overshoots and decays represented optically generated hot electrons, and the plateaus gave the equilibrium temperature increase ΔT, which was in the 30–175 K range. The combination of SFG adsorbate and Au surface reflectance measurements was used to assess the effects of adsorbate vibrational heating by both hot electrons and the hot Au lattice. Two types of SAMs were investigated, nitrobenzenethiolate (NBT), where SFG probed nitro groups located 4 carbon atoms from the surface, and octadecylthiolate (ODT), where SFG probed terminal methyl groups 17 carbon atoms from the surface. With ΔT = 175 K, the NBT nitro transition νs(NO2) showed time-dependent intensity loss, redshifting, and broadening. These three kinds of transients also had overshoot-decay-plateau structures, which resulted from the interplay of hot electron excitation of higher-frequency vibrations including the probed vibration, and Au lattice heating of lower-energy vibrations and the conformational modes that cause reversible disordering of the SAM structure. The relative importance of these effects was different for the overshoot and plateau regions, and for the intensity, redshifting, and broadening effects. With ODT, T-jumps caused the terminal methyl groups to become disordered, and the disordering process was nonexponential in time. From the ratio of symmetric to antisymmetric CH-stretching intensities, the ensemble-averaged methyl tilt angle could be determined. With smaller T-jumps, the methyl groups gradually increased their tilt by a small amount during ∼200 ps, while with larger T-jumps where ΔT = 175 K, the methyl groups abruptly reoriented toward the surface normal and then tilted gradually away from the normal in the next 20 ps.

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Vibrational Sum Frequency Generation Spectroscopy of Interfacial Dynamics

Berg

Dlott

2013

Vibrational Spectroscopy at Electrified Interfaces

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Spatially Resolved Vibrational Energy Transfer in Molecular Monolayers

Cited by 30 publications

References 48 publications

Electron transfer across a thermal gradient

Electron transfer across a thermal gradient

Probing of molecular adsorbates on Au surfaces with large-amplitude temperature jumps

Vibrational Sum Frequency Generation Spectroscopy of Interfacial Dynamics

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