Gas–surface energy exchange and thermal accommodation of CO2 and Ar in collisions with methyl, hydroxyl, and perfluorinated self-assembled monolayers

Lu, Jessica W.; Alexander, William N.; Morris, John R.

doi:10.1039/b921893a

Cited by 25 publications

(28 citation statements)

References 65 publications

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“…For a given collision energy, C 2 F 6 molecules absorb significantly more energy than C 2 H 6 molecules in collisions with Ar, 14 whereas a fluorocarbon surface absorbs much less energy than a hydrocarbon surface in collisions with Ar and other atoms or molecules. 2,9,10,[15][16][17][18] Enhanced internal excitation in C 2 F 6 vs. C 2 H 6 is attributed to the more efficient energy transfer to the lower frequency modes in the heavier species. 19 When fluorocarbon and hydrocarbon chains condense and organize to form surfaces, the inter-chain motions on the hydrocarbon surface have lower frequencies than those on the fluorocarbon surface.…”

Section: Introductionmentioning

confidence: 99%

Kinematics and dynamics of atomic-beam scattering on liquid and self-assembled monolayer surfaces

et al. 2012

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We have conducted investigations of the energy transfer dynamics of atomic oxygen and argon scattering from hydrocarbon and fluorocarbon surfaces. In light of these results, we appraise the applicability and value of a kinematic scattering model, which views a gas-surface interaction as a gas-phase-like collision between an incident atom or molecule and a localized region of the surface with an effective mass. We have applied this model to interpret the effective surface mass and energy transfer when atoms strike two different surfaces under identical bombardment conditions. To this end, we have collected new data, and we have re-examined existing data sets from both molecular-beam experiments and molecular dynamics simulations. We seek to identify trends that could lead to a robust general understanding of energy transfer processes induced by collisions of gas-phase species with liquid and semi-solid surfaces.

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Section: Introductionmentioning

confidence: 99%

Kinematics and dynamics of atomic-beam scattering on liquid and self-assembled monolayer surfaces

et al. 2012

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“…20 Of particular interest to this work, Morris and co-workers have observed CO 2 collisions with OH terminated SAMS and see increased IS scattering compared to CH 3 terminated SAMS, which is ascribed to increased attraction of the quadrupolar CO 2 to the dipole of the OH group overcoming the rigidity of the surface. 21 Contributions from our group have exploited infrared laser absorption methods to monitor the quantum state-resolved rovibrational distribution of scattered molecules as well as high resolution Dopplerimetry to probe final quantum state-resolved translational distributions 22,23 In the present study, we extend these quantum state-resolved laser spectroscopy tools to explore scattering of CO 2 at hyperthermal kinetic energy (15 kcal mol À1 ) from a series of gas-alkali halide/glycerol solutions. One main goal of this work is to exploit the quantum state-resolved scattered flux distributions as a ''messenger'' for the presence/absence of cations or anions in the surface layer.…”

Section: Introductionmentioning

confidence: 99%

On probing ions at the gas–liquid interface by quantum state-resolved molecular beam scattering: the curious incident of the cation in the night time

Gisler

Nesbitt

2012

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There has been a long standing controversy over the preferential presence or absence of cations vs. anions at the gas-liquid interface, dating back to early theoretical efforts by Onsager and co-workers [J. Chem. Phys., 1934, 2, 528]. In the present work, we describe our first efforts to selectively probe ions at the interface via a completely novel approach, based on scattering high energy, jet cooled molecular projectiles from the surface of hydrogen bonded liquids with dissolved alkali halide salts as the source of solvated charges. In particular, this work focuses on preliminary results from quantum state- resolved scattering studies as a function of anion (Cl-, I-), and cation identity (Li+, Na+, K+) in alkali halide/glycerol solutions. By way of physical picture, a quadrupolar projectile such as CO2 preferentially aligns parallel (anions) or perpendicular (cations) to the interface, which could therefore make rotational energy transfer sensitive to the sign of the ion charge. Experimentally, we find that the impulsive scattered (IS) CO2 rotational distributions reveal a clear dependence on anion identity (e.g., hotter for [I-] than [Cl-]), but with essentially no corresponding sensitivity to cation species (e.g., [Li+] indistinguishable from [K+]). Detailed trajectory calculations are used to provide additional insight into the anticipated and observed experimental trends.

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“…Further experimental evidence to support this notion is that the Δ T distribution observed for C 16 /C 4 SAM (Figure d) remains almost identical when the domain size is reduced (Figure S5). Another factor that results in the Δ T contrasts is that accommodation coefficients , of the SAMs for air around the surface might be assumed. According to reported accommodation coefficients of n -alkanethiol SAMs for argon, SAMs with long alkyl chains show a larger accommodation coefficient than those with short alkyl chains, indicating that the former accepts heat from gas more effectively than the latter.…”

Section: Resultsmentioning

confidence: 99%

Visualization of Thermal Transport Properties of Self-Assembled Monolayers on Au(111) by Contact and Noncontact Scanning Thermal Microscopy

et al. 2021

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Thermal transport properties of patterned binary self-assembled monolayers (SAMs) on Au(111) were examined using scanning thermal microscopy (SThM) with both contact and noncontact methods. We fabricated two-dimensional (2D) patterns with two separate domains of n-hexadecanethiol/benzenethiol, benzenethiol/n-butanethiol, or n-hexadecanethiol/n-butanethiol. In the experimental setup, the efficiency of thermal transport from a SThM tip to the SAM surface can be evaluated in terms of the temperature change at the SThM tip. In the contact regime, where a SThM tip physically contacts the SAM surface, direct thermal transport through the SAM and radiation-based thermal transport through the space where SAMs exist may contribute to a drop in temperature at the tip. In the noncontact regime, thermal transport relies on radiation-based heat dissipation from the heated tip to the SAMs. 2D mapping of the spatial temperature distribution on SAMs reflects the difference in thermal transport properties of the two SAM domains. We found that the contact method is effective for visualizing the temperature contrast, which reflects the thermal transport properties of the constituent molecules when the domains of the SAMs have a similar height, while the noncontact method allows visualization of the temperature distribution, which is related to the height of each domain of the SAMs, rather than the chemical structures of the constituent molecules. Combination of contact and noncontact SThM enables 2D imaging of thermal transport properties and topographic imaging simultaneously and represents a new technique for investigating the thermal properties of materials surfaces, which is essential for nanoscale thermal management.

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Gas–surface energy exchange and thermal accommodation of CO2 and Ar in collisions with methyl, hydroxyl, and perfluorinated self-assembled monolayers

Cited by 25 publications

References 65 publications

Kinematics and dynamics of atomic-beam scattering on liquid and self-assembled monolayer surfaces

Kinematics and dynamics of atomic-beam scattering on liquid and self-assembled monolayer surfaces

On probing ions at the gas–liquid interface by quantum state-resolved molecular beam scattering: the curious incident of the cation in the night time

Visualization of Thermal Transport Properties of Self-Assembled Monolayers on Au(111) by Contact and Noncontact Scanning Thermal Microscopy

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