1. Introduction
A starting point for modern research in cavitation dates back to 1917 when Rayleigh provided a theoretical description for the collapse of a spherical void in an unbounded domain of incompressible and non-viscous liquid (Rayleigh Reference Rayleigh1917). The resulting model can be considered the most basic description of cavitation bubble dynamics. Recently, analytical (Kudryashov & Sinelshchikov Reference Kudryashov and Sinelshchikov2014) and approximate analytical (Obreschkow, Bruderer & Farhat Reference Obreschkow, Bruderer and Farhat2012) solutions for the model have been reported, and the equation of bubble oscillation has even been solved for more than three dimensions (Klotz Reference Klotz2013). Rayleigh's derivation uses the conservation of energy, where the potential energy of the fully expanded and empty bubble at ambient pressure $p_{a}$ is converted to kinetic energy within a spherical converging flow field. Given that the bubble is initiated with radius $R_{max}$, the Rayleigh collapse time $T_{C}$ – i.e. the time until the bubble reaches radius zero – can be derived from the continuity equation and the integration of the energy equation:
where $\rho$ denotes the mass density of the liquid. The proportionality constant $0.91468$ is called the Rayleigh factor. Experiments with single cavitation bubbles per se do not start with a void at maximum radius $R_{max}$; instead, these bubbles are seeded from a small radius by depositing energy into a small liquid volume that induces a rapid bubble growth, e.g. through a liquid–vapour phase transition. The energy may be deposited by an underwater detonation, a spark discharge or a focused laser pulse (‘optic cavitation’). The latter technique offers excellent precision on the location of bubble nucleation, and with suitable measures, also excellent repeatability. As a result, at maximum expansion, an almost empty and spherical bubble is formed, sharing its centre with the location of the initial energy deposition. Then the pressure difference between bubble interior and the ambient pressure drives and accelerates the shrinkage of the bubble. This phase of the flow is commonly termed the bubble collapse. The temporal radius evolution and time to collapse are very well predicted by the Rayleigh model and the Rayleigh collapse time $T_{C}^{{Rayleigh}}$ (Lauterborn Reference Lauterborn1972). Under the assumption of Rayleigh collapse, where the liquid is inviscid and the collapsing flow is spherical, the expansion and the collapse phases are symmetrical. Thus we can define the bubble lifetime from the nucleation to collapse as $T_{L}^{{Rayleigh}}=2T_{C}^{{Rayleigh}}$.
In most technical applications with cavitation, however, the bubbles are collapsing at and interacting with material boundaries. There exists an unlimited variety of boundaries. They can be of any geometry and mechanical compliance. From the unlimited variety of boundaries, we chose a planar and rigid wall with dimensions much larger than the bubble dimensions. Such a boundary restricts the liquid flow around the collapsing bubble, and as a consequence, the collapsing bubble develops a rich and non-spherical dynamics together with a complex flow field. A prominent feature is the radial jet that pierces the bubble, shapes it toroidally, and impacts onto the boundary (Plesset & Chapman Reference Plesset and Chapman1971; Lauterborn & Bolle Reference Lauterborn and Bolle1975; Lauterborn & Kurz Reference Lauterborn and Kurz2010). Ring vortices can be formed and can spread along the boundary (Brujan et al. Reference Brujan, Keen, Vogel and Blake2002; Reuter et al. Reference Reuter, Gonzalez-Avila, Mettin and Ohl2017). And with a bubble close to a solid body, significant wall-normal forces and large wall shear stresses can be induced onto the boundary (Krasovitski & Kimmel Reference Krasovitski and Kimmel2004; Dijkink & Ohl Reference Dijkink and Ohl2008; Vos et al. Reference Vos, Dollet, Versluis and de Jong2011; Reuter & Mettin Reference Reuter and Mettin2018; Zeng et al. Reference Zeng, Gonzalez-Avila, Dijkink, Koukouvinis, Gavaises and Ohl2018a). These forces may be exploited or avoided, depending on the use case, e.g. they may be beneficial in ultrasonic cleaning, laser ablation of liquids, or cavitation peening, but are unwanted in cavitation erosion. The precise bubble dynamics is known to depend sensitively on the stand-off distance $d$ of the bubble to the boundary, which is commonly non-dimensionalized by the maximum radius of the bubble as $\gamma =d/R_{max}$ (a sketch is given in figure 1). The significant regime for cavitation material interaction can be considered to be in the range $\gamma <4$, where the long-ranging vortex ring still reaches the boundary (Reuter, Cairós & Mettin Reference Reuter, Cairós and Mettin2016), but for smaller stand-offs, the interaction with the boundary tends to be more intense. Recently, for closest distances to a solid boundary ($\gamma <\approx 0.2$), a needle jet with an impact velocity of over $900\ \textrm {m\ s}^{-1}$ was predicted numerically (Lechner et al. Reference Lechner, Lauterborn, Koch and Mettin2019) and found experimentally (Reuter & Ohl Reference Reuter and Ohl2021). This particular small-distance regime is exploited for the production of nanoparticles by laser ablation in liquids in combination with cavitation bubbles (Barcikowski et al. Reference Barcikowski, Plech, Suslick and Vogel2019). While this small stand-off regime is likely the most relevant for many applications, the Rayleigh lifetime is valid only for large distances, i.e. $\gamma \to \infty$. To derive the lifetime for a bubble at an infinitely extended rigid boundary with potential flow, Rattray (Reference Rattray1951) accounted for the bubble deformation and centroid motion, and obtained with perturbation theory for $\gamma \gg 1$ a modified Rayleigh collapse time $T_{C}=k\,T_{{C}}^{{Rayleigh}}$ with prolongation factor $k(\gamma )=1+{0.205}/{\gamma }$ (Plesset & Chapman Reference Plesset and Chapman1971). Shima & Tomita (Reference Shima and Tomita1981) report on the work of Sato & Shima (Reference Sato and Shima1980), who included surface tension and found, by employing a variational method, a similar factor $k=1+{0.190}/{\gamma }$ for water. These factors $k$, however, are valid only for $\gamma \gg 1$ and weak bubble deformations. In potential flow, for $\gamma \to \infty$ the prolongation factor must approach unity, for decreasing $\gamma$ the prolongation factor must first increase, and for $\gamma \to 0$ the prolongation factor should approach unity again, as the flow field of the hemispherical collapse is of spherical symmetry again. Thus there must be a local maximum of $k$ as a function of $\gamma$.
A few experimental studies reported on the prolongation factor at intermediate stand-offs (Fujikawa & Akamatsu Reference Fujikawa and Akamatsu1978; Shima & Tomita Reference Shima and Tomita1981; Godwin et al. Reference Godwin, Chapyak, Noack and Vogel1999; Shaw, Schiffers & Emmony Reference Shaw, Schiffers and Emmony2001; Chen et al. Reference Chen, Han, Li, Shen, Lu and Ni2011), with only few of them including smaller stand-offs ($\gamma \lesssim 0.6$) (Vogel, Lauterborn & Timm Reference Vogel, Lauterborn and Timm1989; Gregorčič, Petkovšek & Možina Reference Gregorčič, Petkovšek and Možina2007). So far only Yang, Wang & Keat (Reference Yang, Wang and Keat2013) report experimental measurements of the Rayleigh prolongation factor from a larger number of of data points based on single laser-induced bubbles in water. Thus for probably the most relevant regime of cavitation material interaction, there are currently very few experimental data available, which do not allow us to deduce a quantitative description of $k$.
The collapse time should be affected further by the viscosity of the liquid, already in the spherical case but in addition via viscosity-dependent bubble shapes in the near-wall regime (Hupfeld et al. Reference Hupfeld, Laurens, Merabia, Barcikowski, Gökce and Amans2020; Zeng, An & Ohl Reference Zeng, An and Ohl2022).
Here, we measure the prolongation factor for single laser-induced bubbles of millimetre size in water for $\gamma \rightarrow 0$, and compare it with direct numerical simulations using a volume of fluid method. With validated numerics, we study computationally the influence of the viscosity on $k$.
2. Methods
The experimental set-up is shown in figure 1(a). A single bubble is produced in deionized (DI) water with a nanosecond-long laser pulse (Litron nano S, frequency-doubled Nd:YAG) in a glass cuvette (dimensions approximately $50 \times 50 \times 80\ \text {mm}^3$; the open surface in the sketch is located vertically on the right). At the focus, a plasma is generated and a spherical bubble develops. Focusing through the cuvette bottom is achieved with a submerged long-working-distance microscope (Mitutoyo 50x, $NA=0.42$, nominal working distance 20.5 mm, in-house modified with water-tight sealing) after beam expansion. The bubble is generated close to a polished metal slab (2 mm thick brass or stainless steel, $25 \times 25\ \text {mm}^2$) that serves as the rigid boundary. To vary the stand-off distance to the boundary, the metal slab is attached to a motor-controlled micrometre stage. Focusing the laser parallel to the solid boundary avoids the formation of spurious bubbles from the residual light that was not absorbed within the plasma at the laser focus.
A needle PVDF hydrophone (Müller-Platte Needle Probe, rise time $\approx 50$ ns) is positioned at a distance of about 4.5 mm from the spot of plasma generation. The hydrophone is connected to an oscilloscope (Teledyne LeCroy WavePro 404HD) operating at sampling frequency $1$ GHz, with internal low pass with cut-off frequency $500$ MHz. In the acoustic measurements, the instances of bubble generation and bubble collapse become detectable easily as distinct peaks from their respective shock wave emission. The delay between the peaks allows the measurement of $T_{L}$; an example is shown in figure 1(b). This approach is possible as the propagation velocity of the shock waves from seeding and collapse are the same. This is confirmed by tracking the respective shock fronts in a high-speed imaging series with a large field of view of several millimetres (not shown). The reason is that the shock wave propagation velocity approaches the speed of sound already after a few hundred micrometres (Vogel, Busch & Parlitz Reference Vogel, Busch and Parlitz1996), which is less than 10 % of the distance to the hydrophone, and both shock waves are of similar peak pressures. The two main peaks in the image are each followed by a smaller one after about $t_{{d}}=21\ \mathrm {\mu }\text {s}$ from the reflection of the shock wave at the cuvette boundaries, the water surface and in particular the focusing objective. This was also confirmed by schlieren high-speed imaging of the shock front (not shown here). Using the speed of sound in water, the time delay $t_{{d}}=21\ \mathrm {\mu }\text {s}$ corresponds to a travelled distance of $3.15\ \text {cm}$, indicating a distance $1.58\ \text {cm}$ to the nearest cuvette boundary. The bubble shape dynamics is recorded with a long-working-distance microscope objective or a macro lens (Mitutoyo 5x long working distance microscope objective or Canon MP-E 65 mm) with a high-speed camera (Shimadzu HPV-X2) operating at one million frames per second. The exposure time is effectively set as short as 220 fs as the scene is illuminated with a short laser pulse (Ekspla Femtolux, wavelength 515 nm) delivered via a glass fibre. The timing is controlled via a pulse generator (BNC 525, Berkeley Nucleonics, CA) using a LabView script developed to measure the selected stand-off range automatically. The data are evaluated with Matlab and ImageJ. In total, 142 bubbles covering a stand-off range $0.02< \gamma < 1.03$ were evaluated with mean maximum radius $749\ \mathrm {\mu }$m and standard deviation $40\ \mathrm {\mu }$m. The position of bubble generation is highly repeatable to better than one pixel or $3.56\ \mathrm {\mu }$m or $5.50\ \mathrm {\mu }$m, respectively, depending on the imaging objective. We estimate the error in pixel resolution to $1\,\%$. To exclude any potential influence from cavitation erosion on the metal slab, after each bubble event, the slab is moved to a pristine position.
To compare the experimental result, we simulate the laser-induced bubble as a gas bubble using a compressible volume of fluids (VoF) solver accounting for both viscosity and surface tension. The expansion and shrinkage of the bubble during the first cycle can be described with a polytropic equation of state with specific heat ratio $\kappa =1.4$. Although the bubble content is different from the experiment, where the cavitation bubble is a mixture of vapour and various gases (Lauterborn & Kurz Reference Lauterborn and Kurz2010), this treatment has been well validated in our previous works on bubble collapse near a single wall (Zeng et al. Reference Zeng, Gonzalez-Avila, Dijkink, Koukouvinis, Gavaises and Ohl2018a) and within a thin gap (Zeng, Gonzalez-Avila & Ohl Reference Zeng, Gonzalez-Avila and Ohl2020), as well from other groups (Popinet & Zaleski Reference Popinet and Zaleski2002; Koch et al. Reference Koch, Lechner, Reuter, Köhler, Mettin and Lauterborn2016; Li et al. Reference Li, Zhang, Wang, Chen and Li2019). The numerical bubble starts from a spherical gas pocket with radius $50\ \mathrm {\mu }$m and high pressure. This pressure is determined based on the comparison in figure 2, where both the size and period of growth and collapse of the bubble are about the same as the experimental result. The initial pressure is found to be 1400 bar and is kept the same for the following studies. When the bubble reaches maximum expansion, it starts to collapse from the pressure difference ${\rm \Delta} p=p_{{a}}-p_{{i}}$, where $p_{{a}}$ is the ambient pressure, and $p_{{i}}$ is the pressure of the bubble interior. We insert ${\rm \Delta} p$ for $p_{{a}}$ in (1.1), which then reads $T_{C}^{{Rayleigh}}=0.91468\,R_{max}\sqrt {\rho /(p_{a}-p_{i})}$. In the simulations at maximum expansion, $p_{i}$ fluctuates between $2448$ Pa and $2744$ Pa for all simulations carried out here. This is close to the interior pressure expected in the experimental case, which is the water vapour pressure $p_{v}=2339$ Pa. In the following, we use $p_{v}\approx p_{i}$, and calculate the Rayleigh lifetime in all cases according to
Thirty bubbles in the stand-off range $\gamma =0.05$ to $\gamma =1.5$ were simulated with mean maximum radius $699\ \mathrm {\mu }$m and standard deviation $34\ \mathrm {\mu }$m. For details on the simulations, we refer the reader to Zeng et al. (Reference Zeng, Gonzalez-Avila, Ten Voorde and Ohl2018b, Reference Zeng, Gonzalez-Avila and Ohl2020). The numerical bubble lifetime is measured from $t=0$, i.e. the beginning of the simulation to the collapse, which is considered as the instance of minimum gas phase volume that coincides with the shock wave emission as well as the numerical seeding. Experimental and numerical definitions of $T_{L}$ then can be considered the same if the seeding volumes are equal in both cases. Numerically, the bubble is initialized with radius 50 $\mathrm {\mu }$m, which is chosen based on the size of the plasma in the experiment.
The maximum discrepancy between the definitions is negligible as estimated in the following way. A lower boundary for the bubble wall velocity $\dot {R}(t)$ at seeding is given by the simulations as $250\ \text {m\ s}^{-1}$, yielding a difference of less than $100\ \text {ns}$ between the numerical and experimental measurements, which corresponds to less than 0.125 % of $T_{L}$. Thus experimental and numerical procedures on the measurement of the lifetime yield the same results within the experimental uncertainties. The measurements of $R_{max}$ and stand-off distance are depicted in figure 1(c). Even though widely used, the definition of the stand-off $\gamma$ raises some ambiguities when non-spherical bubbles close to boundaries are studied. In the experiments, we define the bubble centre as the centre of the plasma region; see figure 1(c). Also, $R_{max}$ is taken as the distance between the bubble centre and the point reached by the bubble interface farthest from the boundary over the full high-speed framing sequence (which turns out to be identical to the instance of maximum bubble volume). The distance to the boundary $d$ is measured from the centre of the plasma region to the boundary. To determine the boundary position, an appropriate image of the time series is chosen once the bubble and the reflected image of the bubble are visible simultaneously. The boundary location is the location of the mirror axis. This yields a well-defined and robust measurement of $\gamma$. In the theoretical derivations of Rayleigh, due to the energy ansatz, the bubble volume plays a special role, and often an alternative definition of $\gamma$ is used, where $R_{max}^{Veq}$ is taken as an equivalent radius of a sphere that has the same volume as the deformed bubble at maximum (volumetric) expansion.
We benchmark both definitions with our numerical results in Appendix A by calculating the difference between the volumetric definition $\gamma ^{V}$ and the geometric definition $\gamma$ used for the experimental data: ${\rm \Delta} \gamma =\gamma ^{V}-\gamma$. It turns out that $0.009<{\rm \Delta} \gamma <0.023$ in the stand-off interval 0.05 to 1.50. Thus for our purposes, both definitions can be considered to yield almost identical results. In the present experiment, the uncertainty in the measurement of $\gamma$ is smaller than $0.023$, when assuming an uncertainty of 0.5 pixels for measurements of each of the boundary position, the plasma position and the location of the bubble wall, and using the pixel resolution $3.56\ \mathrm {\mu }\text {m}\ \text {px}^{-1}$.
3. Results and discussion
We start with a validation of the numerical simulation by comparing the time evolution of the bubble shapes; see figure 2. The computed bubble interfaces are drawn as red contours superimposed on the experimental images at the same time instance. Times are given in $\mathrm {\mu }$s. Then the bubble is generated at $t=0$, and collapses at $T_{L}$. The experiment and simulation have very close $T_{L}$ values, which are $150.76\ \mathrm {\mu }$s and $150.42\ \mathrm {\mu }$s, respectively. The interframe time of the first six frames is constant at 20 $\mathrm {\mu }$s; from $t=120\ \mathrm {\mu }$s onwards, the interframe time is reduced to resolve the fast collapse dynamics. Note that during the expansion, the bubble acquires a hemispherical shape with its low interface flattened. Then during the collapse, the axial jet indents and pierces the bubble from the boundary-distant pole. At $t=145\ \mathrm {\mu }$s, the bubble interface appears rugged, which is a result of splashing within the bubble following the jet impact onto the boundary. Please note that the numerical image provides a cut through the bubble shape, which allows us to see the jet indentation in the central axis, while in the experimental image, the toroidal shape is projected in the viewing direction. Thus for the first bubble oscillation, experimental and numerical bubble shapes are in excellent agreement. This is the case for the entire stand-off range under investigation here.
From these data, experimentally and numerically, using the acoustic measurement of shock wave emission, the prolongation factor $k=T_{L}/T_{L}^{{Rayleigh}}$ of the lifetime of non-spherical bubbles as compared to the Rayleigh collapse time is measured. Here, $T_{L}^{{Rayleigh}}$ is calculated using (2.1), using mass density $\rho =998\ \text {kg}\ \textrm {m}^{-3}$ and ambient pressure $p_{a}=101.325\ \text {kPa}$. The measured Rayleigh prolongation factor $k$ is presented in figure 3 as a function of the stand-off distance. Regarding the trend, experimental and numerical data show excellent agreement over the entire considered stand-off range. However, the numerics predict a $k$ that is about $2.5\,\%$ larger than the experimental findings. As the main reason that contributes to an overestimation of the numerical collapse time, we identify the shock waves that are emitted during bubble seeding. These are reflected at the domain boundaries and are focused back, much stronger than in the experiment due to the cylindrical symmetry. This reduces mainly $R_{{max}}$ but not $T_{{L}}$ to the same extent, thus increasing $k$. In the experimental data, $k$ may be underestimated as the rigid plane is not extended infinitely but is provided by a metal slab of finite dimensions where the bubble has at least a distance $4\ \text {mm}$ to the closest edge here. An additional systematic error may stem from an error in the imaging scale that we estimate at $1\,\%$, which would effect $k$ linearly. A 7th-degree polynomial $k^{{fit}}=\sum _{i=0}^7 p_i \gamma ^i$ is fitted to the experimental data:
This fit is valid in the $\gamma$ range $0<\gamma <1.0$. Here, the root-mean-square error of the fit is 0.0068. As anticipated, the lifetime increases as the bubble is brought closer to the boundary from infinity. A maximum increase in lifetime is observed for $\gamma =0.69$; thereafter, $T_{L}$ decreases monotonically. Indeed, at $\gamma =0$, the prolongation factor approaches approximately 1, and the fit yields $k^{{fit}}(\gamma =0)=0.978$. For comparison, Rattray's corrections up to first (Rattray Reference Rattray1951; Plesset & Chapman Reference Plesset and Chapman1971) and second (Rattray Reference Rattray1951) order, as well as the correction of Sato & Shima (Reference Sato and Shima1980), are plotted. They are valid only for weak bubble deformations, which explains the divergence from the measured curve in particular for $\gamma <1$. The overestimation for $\gamma >1$ is due mainly to the different definitions of $R_{max}$ and $R_{max}^{Veq}$. In Appendix A, this effect is discussed further, and for comparison, $k$ is presented normalized on the volumetric equivalence radius $R_{max}^{Veq}$. There, we also compare our data with the volumetric numerical data given by Lechner et al. (Reference Lechner, Lauterborn, Koch and Mettin2020). The reduction of the collapse time in the range $\gamma <0.69$ is caused by the approach of the bubble dynamics towards the hemispherical case. The Rayleigh collapse time implies a spherical flow field, which results in the fastest way to collapse a spherical bubble and thus yields the shortest lifetime. The same holds by symmetry considerations for the hemispherical collapse $\gamma =0$ when viscosity is neglected. Thus, in particular, the hemispherical case is characterized by boundary parallel flows, which in the case of a viscous liquid, such as water, can be identified via kinks in the bubble wall (see the arrow in figure 2, at $t=133\ \mathrm {\mu }$s). The smaller $\gamma$, the earlier the kink appears during the dynamics, because the bubble centre reaches the boundary earlier. Consistently with the maximum of $k$ around $\gamma =0.69$ found here, the kinks were shown to appear only for $\gamma <0.73$, for the bubbles under consideration (Reuter & Ohl Reference Reuter and Ohl2021). The flows associated with the kinks can become so dominant for smallest $\gamma$ that they converge and collide at the axis of symmetry even before the regular jet from the apex passes the respective point on the axis. Then a supersonic needle jet is formed in the direction towards the boundary (Lechner et al. Reference Lechner, Lauterborn, Koch and Mettin2019, Reference Lechner, Lauterborn, Koch and Mettin2020; Reuter & Ohl Reference Reuter and Ohl2021).
For a comparison of our data with the data available in the literature, see figure 4; an overview of $R_{{max}}$ is given in table 1. All studies employed laser-induced single bubbles in water and measured the bubble lifetime by acoustic means via detection of the shock wave with different techniques. It should be noted, though, that it seems no work so far had focused in particular on a precise measurement of the Rayleigh prolongation factor in the very small stand-off distance regime. Accordingly, the measurement data available show some significant scatters, and it is difficult to derive a clear trend. Some data sets are based on measurements on differently sized bubbles. In addition, many authors do not specify how the normalized stand-off distance was measured, and sometimes inexact maximum radii where given. For the data provided in Yang et al. (Reference Yang, Wang and Keat2013), we have calculated average values for $k$ to reduce scatter and number of data points. For comparison, our fit is plotted as a solid line. The fit lies in between the literature data, which can be taken as a confirmation of the data, but in addition for $\gamma <0.6$ shows a clear trend to $k\rightarrow 1$.
4. Influence of liquid viscosity and maximum radius
Besides the shown stand-off dependence of $k$, the bubble lifetime may also depend on the viscosity of liquid $\mu$ and to some extend on $R_{max}$ through viscous forces (Ivany & Hammitt Reference Ivany and Hammitt1965; Brennen Reference Brennen2014). We now fix $R_{{max}}\approx 700\ \mathrm {\mu }$m according to our experimental values, and vary the viscosity. One example of the dynamics is shown in figure 5, where we compare the bubble shapes in liquids with two selected viscosities $\mu =10^{-3}\ {\rm Pa}\ {\rm s}$ and $\mu =0.02\ {\rm Pa}\ {\rm s}$ for the same stand-off distance $\gamma =0.52$. In general, the two bubbles undergo similar deformation, but in the liquid with $\mu =0.02\ {\rm Pa}\ {\rm s}$, the bubble expands and collapses more slowly as the drag force owing to viscosity increases. In both cases, during expansion the bubbles acquire a similar hemispherical shape, yet some details of bubble deformation are modified by the higher viscosity. For example, the thickness $h$ of the liquid layer between wall and bubble has increased from about $4\ \mathrm {\mu }$m to $20\ \mathrm {\mu }$m, as a thicker boundary layer has developed (Schlichting & Gersten Reference Schlichting and Gersten2003).
We now present the prolongation factor $k(\gamma )$ for six viscosities, $\mu =10^{-3}$, 0.01, 0.02, 0.03, 0.04 and 0.06 ${\rm Pa}\ {\rm s}$, in figure 6. Viscosity in general and viscous boundary layers are expected to retard the collapse and thus to increase the prolongation factor $k$ for all $\gamma$ values. This occurs monotonically. Still, for all viscosities, $k$ drops quickly for $\gamma \lesssim 0.25$, i.e. when the bubble approaches the hemispherical collapse. At intermediate distances from the boundary, $0.25<\gamma <\gamma _{m}$, $k$ grows slowly to the peak value at $\gamma _{m}$ where the collapse time is longest. For increasing viscosities, this maximum is seen for larger stand-offs, as with higher viscosities the influence of the boundary ranges further into the liquid. For $\gamma > \gamma _{m}$, the lower bubble wall is further from the boundary and thus affected less by the viscous boundary layer. This results in a decrease of $k$ with $\gamma$. Eventually, for $\gamma \rightarrow \infty$, $k$ is expected to approach a minimum that is a function of $R_{{max}}$ and $\mu$ (Proussevitch & Sahagian Reference Proussevitch and Sahagian1998).
Next, we explore the dependency on $R_{max}$ and fix the viscosity at $\mu =1\ {\rm mPa}\ {\rm s}$. In figure 7, $k$ is shown for three maximum radii. All three curves show qualitatively the same behaviour but are scaled by some factor.
In an effort to estimate the respective scalings, we consider a spherical bubble and the normal viscous stresses $p_{\mu }=4{\rm \pi} \mu \dot {R}/R$ (Franc Reference Franc2007) at the bubble interface. Then (2.1) reads
where ${\rm \Delta} p=p_{a}-p_{v}$. With characteristic radius $R=R_{max}$ and deformation rate $\dot {R}=R_{max}/T_{C}^{{Rayleigh}}$, one obtains a viscosity modified collapse time $T_{C}^{\mu }$, and consequently a viscosity modified prolongation factor for the spherical case:
where for the approximation, the square root has been linearized.
However, this scaling clearly fails to predict the results, in particular as it largely underestimates the prolongation factor. For example in figure 7, (4.2) would predict a negligible factor of only $1.0012$ between $k(R_{{max}}=1300\ \mathrm {\mu }\text {m})$ and $k(R_{{max}}=400\ \mathrm {\mu }\text {m})$, while the numerical results show a factor of around $1.036$ between the two curves. To understand if the prolonged collapse time is due to viscous dissipation in the boundary layer, we conducted simulations where the boundary condition at the wall has been altered to free slip. Interestingly, even at the higher viscosities, this had only a minor influence on $k$ for $\gamma <0.9$, and did not affect significantly the prolongation factor at all for $\gamma >0.9$. Thus the prolongation due to viscosity stems from the entire non-spherical flow field, which is known to have a complex structure (Zeng et al. Reference Zeng, An and Ohl2022). This observation may help to derive an appropriate scaling of the prolongation factor that accounts for viscosity, too.
5. Conclusions
We measured experimentally and numerically the prolongation factor $k$ of the lifetime of a single cavitation bubble that collapses near a rigid boundary in water. Simulations and experiment show the trend of $k(\gamma )$ in excellent agreement, but the simulation predicts a value about $2.5\,\%$ larger for all stand-offs. The longest lifetime in water is found for $\gamma =0.69$ in both the numerics and experiments with $k \approx 1.2$. It decreases quickly for smaller stand-off distances where the dynamics approaches an ideal hemispherical collapse. The numerical parameter study of $k(\gamma )$ for smaller ratios $R_{{max}}/\mu$ shows, besides a general increase of the prolongation factor, a shift of the maximum collapse time towards larger stand-offs. Even though during most of the bubble lifetime – i.e. up to a few microseconds before the bubble collapse – similar bubble shapes are observed independently of the viscosity, a general scaling over a wide range of maximum radii and viscosities seems difficult, as the substantial viscous dissipation is associated with the entirety of the complex, non-spherical flow field. These experimentally confirmed data could be useful for the validation of numerical simulations of single bubble dynamics, for evaluation of the distance of bubbles for surface treatment and particle generation (Soyama Reference Soyama2015; Barcikowski et al. Reference Barcikowski, Plech, Suslick and Vogel2019), and to test advanced analytical models of the collapse at small stand-off distances.
Acknowledgements
We thank Dr R. Mettin from the University of Göttingen for lending us laser equipment.
Funding
This research was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under grant OH 75/4-1.
Declaration of interests
The authors report no conflict of interest.
Appendix A. On the definition of $\gamma$ and the prolongation factor for the equivalent volumetric maximum radius $R_{max}^{Veq}$
In figure 8, the Rayleigh case of a bubble at a boundary is shown. The geometric definition of $R_{max}$ as we use it throughout this paper and explain in the experimental section is appropriate to describe the hemispherical collapse (figure 8a). For comparison, the definition of the maximum radius from a volume equivalent is shown too; see figure 8(b). In that case, the bubble is described by a sphere of an effectively smaller radius. The two radii are related by $R_{max}^{Veq}=\sqrt [3]{\frac {1}{2}} R_{max}$ for this ideal Rayleigh case of bubbles of spherical cap shape.
In figure 9, we show the same data as in figure 3, but this time as functions of $\gamma ^{{V}}$ and scaled on $R_{max}^{Veq}$, i.e. $k_{{Veq}}=T_{{L}}/(0.1837\,R_{max}^{Veq} \text {m}^{-1}\ \textrm {s})$. As expected, in the range $\gamma >1$, the measured data fit the theoretical predictions by Rattray or Sato & Shima better as the latter are based on a volumetric definition. For $\gamma \rightarrow 0$, the deviations from the theoretical descriptions again are large, and $k_{{Veq}}$ does not approach a prolongation factor of unity for the hemispherical case but seems to approach $\sqrt [3]{2}$. This is because effectively, it predicts the collapse time of a bubble of the smaller radius $R_{max}^{Veq}$.
While $k$ has a maximum at $\gamma =0.69$, with this scaling, $k_{{Veq}}$ rather shows a plateau when $\gamma \rightarrow 0$. This is because with decreasing $\gamma$, the value of $R_{max}^{Veq}$ decreases as the bubble volume decreases, as sketched in figure 8.
In figure 9 the numerical results by Lechner et al. (Reference Lechner, Lauterborn, Koch and Mettin2020) are plotted additionally (orange triangles). They agree well in trend and in values with our results. However, an additional fluctuation with a local minimum around $\gamma = 0.25$ is seen, which is not present in our data. Kindly note that their data was normalized on a fixed value of $R_{max} = 500\,{\rm \mu}{\rm m}$ measured on one free bubble, neglecting the effects of the boundary on the bubble size. Furthermore, their data is measured on the collapse phase only and not over the entire bubble life time; for details see Lechner et al. (Reference Lechner, Lauterborn, Koch and Mettin2020).
In the following, we work out the relationship between the volumetric and geometric definitions, and also give a conversion function derived from our simulations that we used to re-scale our experimental data in figure 9. This is justified by the perfect matching of bubble shapes at maximum expansion (see figure 2). In figure 10, the relation $R_{max}^{Veq}/R_{max}$ is shown together with the fit function given in (A1) below. For the fit, we use a rational of the form $p_1 x^4 + p_2 x^3 + p_3 x^2 + p_4 x + p_5)/ (x^4 + q_1 x^3 + q_2 x^2 + q_3 x + q_4)$, and find the fit parameters
with a root-mean-square error 0.0008 in the range shown in figure 10. For $\gamma =0$, the fit yields, as expected, ${0.06398/0.08072=0.793}\approx 0.7937=\sqrt [3]{\frac {1}{2}}$. The data also allow us to convert $\gamma$ to $\gamma ^{{V}}$ easily according to $\gamma ^{{V}}=\gamma \,R_{max}/R_{max}^{Veq}$; the numerical results are shown in figure 11. Finally, we consider the difference in stand-off values between the volumetric and geometric stand-off definitions, $\gamma ^{{V}}-\gamma$; see figure 12. It turns out that the difference between the definitions is below $0.022$ for all stand-offs. This small value is often negligible and within the range of measurement errors. The maximum radius, however, varies for both definitions up to a factor $\approx 2^{1/3}$ (at $\gamma =0$).
Note that for $\gamma \rightarrow \infty$, both definitions are the same. Here we chose to use the geometric definition because it allows the correct prediction of the collapse time for $\gamma =0$ and $\gamma \rightarrow \infty$, and we feel that it is the adequate description for the hemisphere, while with the volumetric stand-off, this is only the case for $\gamma \rightarrow \infty$. In addition, the geometric definition offers some experimental advantages that we use here because it is sufficient to measure the bubble boundary at only one position, while for a volumetric measurement the boundary needs to be determined along the entire bubble contour, along which, typically, the illumination conditions change, in particular when close to the solid.