Dynamic wetting and gas viscosity effects

“…A similar paradox is encountered for air entrainment by rapidly advancing contact lines, where a liquid advances over a surface that it partially wets [2,23,39,[62][63][64]. Once again, it was found that depressurizing the gas leads to a significant increase of the threshold of air entrainment [23,65]. This contradicts the classical viewpoint that, for given wettability, the contact line speed depends mainly on the liquid properties as ∼ γ/η ℓ [9,12,21,39], with minor influence of the gaseous phase.…”

“…A pressure reduction does not affect the dynamical viscosity of a gas [71]. However, as also mentioned in [23,65], it does increase the mean free path ℓ mfp by a factor ℓ mfp ∼ p atm /p. Since under atmospheric conditions ℓ mfp ≈ 70 nm, the mean free path is pushed well into the micron range when pressure is reduced by a factor 100.…”

“…We explain this by the influence of the air flow when the local angle of the interface is close to π. Can such a scenario explain the observed increase of entrainment speed when depressurizing the air [23,65]? A pressure reduction does not affect the dynamical viscosity of a gas [71].…”

“…When the plate is moving beyond a critical speed, the meniscus can no longer equilibrate to a steady state. In the case of receding contact lines (withdrawing plate) this leads to the deposition of a liquid film [3, 12-14, 18, 74, 75], while air will be entrained for advancing contact lines [2,23,39,[62][63][64][65]76].…”

Dynamical wetting transition: liquid film deposition and air entrainment

“…A similar paradox is encountered for air entrainment by rapidly advancing contact lines, where a liquid advances over a surface that it partially wets [2,23,39,[62][63][64]. Once again, it was found that depressurizing the gas leads to a significant increase of the threshold of air entrainment [23,65]. This contradicts the classical viewpoint that, for given wettability, the contact line speed depends mainly on the liquid properties as ∼ γ/η ℓ [9,12,21,39], with minor influence of the gaseous phase.…”

“…A pressure reduction does not affect the dynamical viscosity of a gas [71]. However, as also mentioned in [23,65], it does increase the mean free path ℓ mfp by a factor ℓ mfp ∼ p atm /p. Since under atmospheric conditions ℓ mfp ≈ 70 nm, the mean free path is pushed well into the micron range when pressure is reduced by a factor 100.…”

“…We explain this by the influence of the air flow when the local angle of the interface is close to π. Can such a scenario explain the observed increase of entrainment speed when depressurizing the air [23,65]? A pressure reduction does not affect the dynamical viscosity of a gas [71].…”

“…When the plate is moving beyond a critical speed, the meniscus can no longer equilibrate to a steady state. In the case of receding contact lines (withdrawing plate) this leads to the deposition of a liquid film [3, 12-14, 18, 74, 75], while air will be entrained for advancing contact lines [2,23,39,[62][63][64][65]76].…”

Dynamical wetting transition: liquid film deposition and air entrainment

“…Recently, Benkreira and Khan (2008) and Benkreira and Ikin (2010) demonstrated in a series of dip coating experiments in an environment comprising gas other than air that the viscosity of the very thin gas film entrained by the moving substrate also played a critical role. Using helium at very low pressures (~25mPa), they measured gas entrainment speeds that were much higher (as much as 3 times larger) than the air entrainment speed under atmospheric pressure.…”

Slot coating minimum film thickness in air and in rarefied helium

Reverse roll-coating flow: a computational investigation towards high-speed defect free coating