3.1. Steady flow at low $Wi$

As flow approaches the contraction at $Wi\leq 5$, a steady separation point forms where the flow separates from the walls of the channel and passes as a central jet through the constriction. Evidently, the minimum $Wi$ achieved in our experiments precludes possible observation of lip vortices, which occur at lower $Wi$ than the onset of jetting behaviour and the appearance of corner vortices (e.g. Rothstein & McKinley Reference Rothstein and McKinley2001). Additionally, although we do not track particle positions in our measurements, it was visually observed that flow entered the corner vortex from the midplane, i.e. the inverted state found by Alves et al. (Reference Alves, Pinho and Oliveira2008) and Sousa et al. (Reference Sousa, Coelho, Oliveira and Alves2009), indicating strong extensional effects. Figure 2 presents (a) average isosurfaces and (b) a midplane $x^* - y^*$ slice of the streamwise velocity $u_x^*$ for $Wi = 5$. The pink isosurface shows $u_x^* = 1/3$ (i.e. the central jet), while the grey surface marks $u_x^* = 0$ (i.e. the edges of the recirculating regions). Flow separation follows the upstream down zero-crossing of $u_x^*$; the central jet is characterized by positive $u_x^*$, while the corner vortices drive negative $u_x^*$ backflow along the walls towards the separation point.

Figure 2. Averaged (a) isosurfaces and (b) midplane $x^* - y^*$ slice of the streamwise velocity $u_x^*$ at $Wi = 5$. The isosurfaces in (a) are pink for $u_x^* =1/3$ and grey for $u_x^* = 0$. The dashed red line in (a) marks the $u_x^*$ extraction used in figure 3.

3.2. The onset of periodic instability

For increasing $Wi$, the corner vortex propagates upstream but remains steady, until, for $Wi>Wi_p$, the flow transitions to a periodic instability characterized by axial fluctuation of the upstream separation point and a circumferential precession of the central jet (see supplementary movie 1 available at https://doi.org/10.1017/jfm.2021.620 for animations of the jet for $5 \leq Wi \leq 44$). Note that a similar helical flow pattern was previously postulated by Rothstein & McKinley (Reference Rothstein and McKinley2001) for an axisymmetric contraction. They observed it as azimuthal motion of a local jet separating from the lip near the corner vortex, and suggested that the jet lined the boundary of the corner vortex. Our results validate their hypothesis: a jet starts from the upstream separation point, propagates through the centreline of the channel, and as a global flow instability forms a helical jet moving towards the contraction along the length of the vortex.

Figure 3(a–e) present space–time diagrams depicting the streamwise flow velocity $u_x^*(x^*)$ along the line $(y^*, z^*)=(-w_0/w_c, 0)$ (dashed red line in figure 2a) for five representative values of $3\leq Wi \leq 87$. The dimensionless vortex length $L^*_v$ is determined by the zero-crossing of $u_x^*$ (as indicated on figure 3a). The average value of $L^*_v$ ($L_{v,avg}^*$) and the range of oscillation between $L_{v,max}^*$ and $L_{v,min}^*$ are plotted as functions of $Wi$ in figure 3(f), indicating a transition from steady vortex growth at lower $Wi$ to a regime of oscillation where $L_v^*$ apparently no longer scales directly with $Wi$. The inset of figure 3(f) shows the period of oscillation ($T^{*} = T / \lambda$) determined by fast Fourier transform of the $L_v^*(t)$ signals. Above the critical value $5< Wi_p \leq 11$ for the onset of oscillation, the range of oscillation reaches a local maximum by $Wi=16$, and the mean separation point actually moves downstream (i.e. $L_v^*$ reduces) for $22\leq Wi \leq 44$. Interestingly, the reduction in $L_v^*$ does not affect the frequency of the instability, with the period of oscillation continuously decreasing from $T^{*}= 26$ at $Wi = 11$ to $T^{*}= 7$ at $Wi = 44$ (figure 3f).

Figure 3. (a–e) Space–time diagrams of the streamwise velocity $u_x^{*}$ (indicated by the colour bars) along the wall at the $x^{*} - y^{*}$ midplane (represented as a dashed line in figure 2a) for (a) $Wi = 3$, (b) $Wi = 5$, (c) $Wi = 11$, (d) $Wi = 22$ and (e) $Wi = 87$. (f) The mean and range of values of $L^{*}_{v}$, with the fundamental period $T^{*}$ in the inset.

Our results expand on prior experiments in axisymmetric abrupt contractions which saw the vortex size increase monotonically for increasing $Wi$, although at a lower $Wi$ range than probed here due to larger length scales involved (e.g. $Wi < 5$ for McKinley et al. (Reference McKinley, Raiford, Brown and Armstrong1991) and $Wi < 8$ for Rothstein & McKinley (Reference Rothstein and McKinley1999)). In planar microfluidic contraction flow experiments, Rodd et al. (Reference Rodd, Cooper-White, Boger and McKinley2007) reported a decrease in $L^*_v$ for a single data point at the maximum $Wi = 24$ achieved, but were unable to extrapolate the trend. Numerical work by Comminal et al. (Reference Comminal, Hattel, Alves and Spangenberg2016) revealed an $L^{*}_v$ plateau accompanied by periodic vortex annihilation for $Wi > 14$ in a 2-D contraction, which they attributed to an accumulation of elastic strain upstream of the contraction. However, they acknowledged that their use of the Oldroyd-B constitutive model (Oldroyd Reference Oldroyd1950) lacks physical mechanisms (such as finite extensibility) which would otherwise limit elastic stress.

3.3. Out-of-plane jet dynamics

As shown in the $x^* - t^*$ space–time diagrams in figure 3(a–e), the flow instability is strongly periodic for $Wi \geq 11$. Thus, to collapse the dataset and further reduce noise, we deploy time-synchronous averaging (TSA) to reduce the time dimension to a single average cycle. This method is further discussed in Bechhoefer & Kingsley (Reference Bechhoefer and Kingsley2009). We isolated the time series of velocity magnitude at a single point in the volume, and then used the local maxima in the time series at that point to segregate each period at all points in the volume. The cycles are mapped to a normalized phase time $\phi ^*$ ranging from 0 to 1 (i.e. one cycle), and averaged into $f_{s}T$ bins, where $f_{s}$ is the sampling frequency (12 Hz) and $T = T^{*}/\lambda$ is the average period ($T^{*}$ shown in figure 3f). Henceforth, phase-averaged quantities will be marked by $\langle {~}\rangle$.

We used the phase-binned data to investigate the 3-D trajectory of the central jet passing through the toroidal corner vortex. We found the maximum flow velocity in each $y^* - z^*$ plane along the $x^*$ axis for $-L_v^* \leq x^* \leq 0$, and took the $y^* - z^*$ coordinates of the peak velocity as the location of the core of the jet in $x^*$. Thus, we extract $x^* - y^* - z^*$ trajectories of the circulating inner jet as it approaches the contraction. To quantify fluctuations in the jet velocity throughout phase time, we calculate the normalized fluctuating velocity along $x^*$ as $\langle \hat {U} \rangle (\phi ^*) = (1/n_{x^*})\sum _{x^*=0}^{x^*=L_v^*}[\langle U \rangle ^*(x^*,\phi ^*)-{\langle \bar{U}\rangle ^*}(x^*)]/\langle U \rangle ^*(x^*)_{max}$. In this way $\langle \hat {U} \rangle$ is not affected by the accelerating flow velocity as the jet approaches the contraction, and is normalized to compare between different $Wi$ values.

Data of $\langle \hat {U} \rangle$ are presented in figure 4(a) for $Wi \geq 5$, along with snapshots of the location of the jet and planar projections of the swept area of the circulating jet core in figure 4(b,c) for $Wi = 44$ and $Wi = 87$ (trajectories in figure 4(b,c) are coloured by their $\phi ^*$ value in figure 4(a) for comparison). Note that we observe a phase-wise asymmetry of the jet in both the normalized fluctuating component of velocity and the jet location. For each $Wi$, the jet starts at the same place in the channel at $\phi ^* =0$; however, the directionality of the precession about $x^*$ is seemingly random between experiments. Maxima and minima in $\langle \hat {U} \rangle$ are evident for $Wi = 11$ near $\phi ^*$ = 0.18, 0.88 and 0.56, and are apparent but slightly degraded by $Wi=22$. The fact that the velocity fluctuation is small (less than $5\,\%$) and almost symmetric about $\phi ^* = 0.5$ indicates that the cyclical fluctuation in the $11\leq Wi \leq 22$ regime is likely to be geometric in origin as the channel has an approximately $5\ \mathrm {\mu }\textrm {m}$ (or approximately $0.02w_c$) variation between the width and height. At higher $Wi$ (e.g. $Wi = 44$ and $Wi=87$), the jet had the same directionality as for $Wi = 22$ and was mapped to the same locations in phase time, but strikingly the dual $\langle \hat {U} \rangle$ peaks are eliminated. Instead, we observe a single minimum and maximum for $\langle \hat {U} \rangle$ and the values occur at different phase times from those seen at lower velocities. Thus it is inferred that the peak fluctuation is independent of the $y^* - z^*$ coordinate between different $Wi$.

Figure 4. (a) The axially averaged normalized fluctuating velocity $\langle \hat {U} \rangle$ of the jet over phase time $\phi ^*$. (b,c) Trajectories of the jet core (coloured by $\phi ^*$ in (a)) and planar projections of the swept area of the core (in grey) at $Wi$ = 44 and 87.

To relate velocity fluctuations within the jet to the spatial distribution, we present in figure 4(b,c) trajectories of the jet core position in $x^* - y^* - z^*$ over phase time. Here we see that the minimum $\langle \hat {U} \rangle$ for $Wi=44$ coincides with a skewed curvature of the jet towards $+z^*$ near $\phi ^* = 0.42$, and the jet is comparatively tighter towards $z^* = 0$, which aligns in time with the maximum $\langle \hat {U} \rangle$ near $\phi ^* = 0.78$: the distribution of the jet varies inversely with the fluctuating velocity such that the flow rate is preserved. A similar effect is seen for $Wi= 87$, but with a shifted phase timing of $\langle \hat {U} \rangle$, placing the asymmetry more in the $x^* - y^*$ plane. Reconfiguration to single-sided asymmetry in the jet at $Wi\geq 44$ coincides with a phenomenon previously discussed: the growth plateau in $L^*_v$ from $11\leq Wi \leq 22$ despite a decreasing core period of the circulating jet (figure 3f). Whereas the symmetrically swirling jet appears to prohibit vortex growth, a break to strong asymmetry above $Wi = 22$ proves a preferable route and $L^*_v$ again increases for increasing $Wi$.

3.4. The role of the rate-of-strain tensor

Dilute solutions of high-molecular-weight polymers are known to shear-thin under shear flow and to strain-harden under extensional deformations (Tirtaatmadja & Sridhar Reference Tirtaatmadja and Sridhar1993; Solomon & Muller Reference Solomon and Muller1996), as we observed for the HPAA fluid used in our work (figure 1b,c). Furthermore, as shown via steady-state 3-D simulations at high $Wi$ in Afonso et al. (Reference Afonso, Oliveira, Pinho and Alves2011), regions of purely extensional flow are expected near the centreline of the channel. We can gain qualitative insight into the relevance of strain hardening to the dynamics of our microcontraction flow by considering the local rate-of-strain tensor $\boldsymbol{\mathsf{D}} = (\boldsymbol {\nabla } \langle \boldsymbol {u}\rangle +\boldsymbol {\nabla } \langle \boldsymbol {u}\rangle ^\textrm {T})/2$. Here we rely solely on the $\mathrm {\mu }$-TPIV measurements to obtain the velocity vector field before calculating $\boldsymbol{\mathsf{D}}$. We take the magnitude of $\boldsymbol{\mathsf{D}}$ as $\langle \dot {\gamma }\rangle = \sqrt {2(\boldsymbol{\mathsf{D}}\boldsymbol {:}\boldsymbol{\mathsf{D}})}$ (reduced as $\langle \dot {\gamma }\rangle ^* = \langle \dot {\gamma }\rangle w_c / (2 U_c)$) to highlight regions of high rate of strain where strain hardening of the HPAA is more likely.

We extracted $y^* - z^*$ slices at an arbitrary $x^* = -8$ for $Wi = 87$ to show a simplified perspective on the relationship between $0.5\langle \dot {\gamma }\rangle ^*$ and the location of the jet (coloured contours of $0.5\langle U \rangle ^*$, where $\langle U \rangle ^*= \langle U \rangle / U_{c}$) in figure 5(a–d). The individual panels progress along phase time $\phi ^*$, with each plane including the $0.5\langle U \rangle ^*$ contour from the following phase time. Red arrows connect circular markers for the locations of maximum velocity on the plane between time steps with the tail and head markers showing the present and future positions, respectively. Two trends are noted: First, while the jet (the solid coloured contour) stays centred about $\langle \dot {\gamma }\rangle ^*$, the jet location forward in time is always towards the exterior of the $\langle \dot {\gamma }\rangle$ contour. Second, a phase-wise asymmetry manifests in the distribution of $\langle \dot {\gamma }\rangle ^*$: $\phi ^* = 0.12$ has low asymmetry in $\langle \hat {U} \rangle$ (figure 5b) as well as in the distribution of $\langle \dot {\gamma }\rangle$; at $\phi ^* = 0.62$, $\langle \hat {U} \rangle$ is highly deviated and this aligns with a strong mismatch in $\langle \dot {\gamma }\rangle ^*$ about the circumference of the jet. Therefore, it appears that a mismatch in rate of strain about the jet can strongly influence the phase-wise progression of the jet as it circulates, with positive and negative fluctuations in $\langle \hat {U} \rangle$ accompanied by an imbalanced distribution of $\langle \dot {\gamma }\rangle ^*$.

Figure 5. A sequence of $y^* - z^*$ slices showing $\langle \dot {\gamma }\rangle ^*$ at $x^* = -8$, with black contours of $0.5\langle \dot {\gamma }\rangle ^*$ and coloured contours of $0.5\langle U\rangle ^*$ for $Wi = 87$, for increasing normalized phase time $\phi ^*$. Red arrows mark the direction between $\phi ^*$ steps of the location of the maximum velocity on the plane (the small white circles), with the tail and head markers showing the present and future positions, respectively.

In figure 6, we present isosurfaces of $0.5\langle \dot {\gamma }\rangle ^*$ and $0.5\langle U \rangle ^*$, the maximum rate of strain and flow velocity, for $Wi= 87$. Figure 6(a–d) show four time steps throughout a circulation, where the volume of high rate of strain forms a band about the circumference of the core of the jet (the pink isosurface). Moreover, the $\langle \dot {\gamma }\rangle ^*$ isosurface extends further upstream on one side of the jet for all time steps, i.e. the rate of strain is greater along one side of the jet. An animated loop of the jet circulating with the rate-of-strain volume is shown in supplementary movie 2. We directly compare the rate of strain forward in time in figure 6(e) as projections of $\langle \dot {\gamma }\rangle ^*$ from (a–d) from the $-x^*$ direction. Moving clockwise from the $\phi ^*=0.12$ isosurface, each surface forward in time presents a decrease in the rate of strain in the clockwise direction or, in other words, a perpetual retreat of the central jet from regions of increased rate of strain. The dynamics of elastic contraction flow has been reported to be sensitive to the extensional rheology (Rothstein & McKinley Reference Rothstein and McKinley2001; Alves & Poole Reference Alves and Poole2007), and since our HPAA solution strain hardens (figure 1c), we can infer from the flow kinematics that the central jet moves about the contraction driven by gradients of strain-hardening HPAA, which will tend to follow the regions of increased rate of strain. This sheds new light onto the likely significance of extensional rheology for local dynamics in viscoelastic contraction flow, as experimentally describing flow topology via directly resolving the rate-of-strain tensor has not been achieved hitherto for elastic flow instability.

Figure 6. (a–d) Phase-averaged isosurfaces of $0.5\langle \dot {\gamma }\rangle ^*$ and $0.5\langle U\rangle ^*$ for $Wi= 87$. (e) The $-x^*$ projection of the $\langle \dot {\gamma }\rangle ^*$ surfaces from (a–d), coloured by their normalized phase time $\phi ^*$. For advancing time $\phi ^*$, the inner jet displaces towards decreasing rate of strain.