Statistical Rate Theory Examination of Ethanol Evaporation

The range of applicability of a fundamental tool for studying the evolution of droplets, the radius-square-law, was investigated both analytically and numerically, on the basis of the experimental results of our own as well as of other authors. Standard issues were briey discussed. Departures from the radius-square-law caused by the inuence of impurities encountered in non-ideal liquids, by the kinetic and surface tension eects encountered for small droplets or by thermal imbalance encountered in light-absorbing droplets were analysed. The entanglement between the kinetic and impurities eects was studied numerically yielding a possible explanation to evaporation coecient discrepancies found in the literature.An unexpected radius-square-law persistence in case of non-isothermal evolutions of very small droplets in atmosphere nearly saturated with vapour was analysed. The coexistence of the kinetic eects and the strong eects of surface tension was found responsible for this eect.

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“…A new attitude is often sought. The application of statistical rate theory (SRT) [8,9] or irreversible thermodynamics [10,11] make an example.…”

Section: Introductionmentioning

confidence: 99%

Evaporation of Micro-Droplets: the "Radius-Square-Law" Revisited

et al. 2012

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“…During each experiment, the temperatures and the temperature gradients in each phase were measured at 10 positions along the interface. A coupled system of equations was formed that included the statistical rate theory (SRT) expression for the evaporation flux [16][17][18] and solved to predict the droplet shape and the evaporation rate. These predictions are evaluated by comparing the measured droplet shape and the measured pumping rate with those FIG.…”

mentioning

confidence: 99%

“…Because of symmetry, the thermocapillary convection vanishes at the droplet apex [17,18]. The evaporation flux at this point, j ev ð0Þ, is determined from the measured temperatures and temperature gradients in each phase and Eq.…”

mentioning

confidence: 99%

Energy Transport by Thermocapillary Convection during Sessile-Water-Droplet Evaporation

2010

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The energy transport mechanisms of a sessile-water droplet evaporating steadily while maintained on a Cu substrate are compared. Buoyancy-driven convection is eliminated, but thermal conduction and thermocapillary convection are active. The dominant mode varies along the interface. Although neglected in previous studies, near the three-phase line, thermocapillary convection is by far the larger mode of energy transport, and this is the region where most of the droplet evaporation occurs.

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“…3). We also note that neglecting conformational effects in hydrocarbons in which evaporation rate is treated with a temperature-dependent term has been proposed by Elliott and War 18, 23 . We used equation (3) to fit the experimental evaporation rate of binary fuel of n -heptane and n -hexadecane hydrocarbons reported by Ghassemi and co-workers 44 at different pressures and temperatures.…”

Section: Resultsmentioning

confidence: 83%

Specificity Switching Pathways in Thermal and Mass Evaporation of Multicomponent Hydrocarbon Droplets: A Mesoscopic Observation

Nasiri

Luo

2017

Sci Rep

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For well over one century, the Hertz–Knudsen equation has established the relationship between thermal – mass transfer coefficients through a liquid – vapour interface and evaporation rate. These coefficients, however, have been often separately estimated for one-component equilibrium systems and their simultaneous influences on evaporation rate of fuel droplets in multicomponent systems have yet to be investigated at the atomic level. Here we first apply atomistic simulation techniques and quantum/statistical mechanics methods to understand how thermal and mass evaporation effects are controlled kinetically/thermodynamically. We then present a new development of a hybrid method of quantum transition state theory/improved kinetic gas theory, for multicomponent hydrocarbon systems to investigate how concerted-distinct conformational changes of hydrocarbons at the interface affect the evaporation rate. The results of this work provide an important physical concept in fundamental understanding of atomistic pathways in topological interface transitions of chain molecules, resolving an open problem in kinetics of fuel droplets evaporation.

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Statistical Rate Theory Examination of Ethanol Evaporation

Cited by 31 publications

References 31 publications

Evaporation of Micro-Droplets: the "Radius-Square-Law" Revisited

Evaporation of Micro-Droplets: the "Radius-Square-Law" Revisited

Energy Transport by Thermocapillary Convection during Sessile-Water-Droplet Evaporation

Specificity Switching Pathways in Thermal and Mass Evaporation of Multicomponent Hydrocarbon Droplets: A Mesoscopic Observation

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