2.1. Flow apparatus

The experimental facility is the TU Wien Turbulent Water Channel, consisting of a 10 m long water channel, constructed by combining five sections of 2 m each, with cross-sectional dimensions of $80\ \textrm {cm}\times 8\ \textrm {cm}$ ($w\times 2h$, where $h$ is half-channel height). Each section of the channel is equipped with de-airing valves, which allows the removal of bubbles trapped close to the top wall of the channel. The channel is manufactured using poly(methyl methacrylate) with a thickness of 1.5 cm, which is fully transparent. The experimental set-up is sketched in figure 1(a). The upper cover of the channel is removable in all sections, and both open- and closed-channel experiments can be performed. In this study, we only consider the closed-channel configuration with no free surface. The fluid is circulated from the downstream to the upstream reservoir by a pump, and the flow is subsequently driven by gravity. A centrifugal volute pump (maximum flow rate of $147\ \textrm {m}^{3}\ \textrm {h}^{-1}$) and a Proline Promag 10D electromagnetic flowmeter are used. Average temperature of the water is kept at $15\,^{\circ }\textrm {C}$, which results in a dynamic viscosity equal to $\mu =1.138\times 10^{-3}\ \textrm {Pa}\ \textrm {s}$ (Korson, Drost-Hansen & Millero Reference Korson, Drost-Hansen and Millero1969). In order to eliminate all vibrations, possibly created by either the pump or the chiller of the laser, both equipments are placed on vibration isolators.

Figure 1. Schematic of the TU Wien Turbulent Water Channel and test section. (a) The system consists of two reservoirs at ambient pressure, a centrifugal pump and a rectangular channel (aspect ratio of 10). The test section is located 8.5 m downstream of the channel entrance, to ensure a fully developed turbulent flow. (b) Close-up view of the test section, where an array of four cameras is used to record the three-dimensional motion of the particles. The laser volume, indicated by the green region, is located at the channel mid-span. To reduce the optical image distortion due to astigmatism, cameras look through prisms filled with water. The laboratory reference frame ($x,y,z$, respectively streamwise, wall-normal and spanwise directions) is also shown. (c) Field of view of the cameras and illumination volume.

2.2. Flow and fibre properties

In all experiments, a constant flow rate of $39.6\ \textrm {m}^3\ \textrm {h}^{-1}$ has been chosen, corresponding to a bulk velocity of $0.172\ \textrm {m}\ \textrm {s}^{-1}$ and a bulk Reynolds number based on channel full height ($2h$) of $\textit {Re}_{b}=12\,500$. The shear velocity of the unladen flow is $u_{\tau }=10.2\ \textrm {mm}\ \textrm {s}^{-1}$, which gives a friction Reynolds number $\textit {Re}_{\tau }=u_{\tau }h/\nu =360$, where $\nu$ is the kinematic viscosity of water at $15\,^{\circ }\textrm {C}$. Viscous time and length scales of the flow are $\tau =\nu$/$u_{\tau }^2\approx 11$ ms and $\delta =h/\textit {Re}_{\tau }\approx 110\ \mathrm {\mu }\textrm {m}$, respectively. Kolmogorov time and length scales of the flow at the centre of the channel are computed as $t_{\eta }=(\tau ^{2}/\epsilon _{d}^+)^{0.5}\approx 220$ ms and $l_{\eta }=(\delta ^{4}/\epsilon _{d}^+)^{0.25}\approx 500\ \mathrm {\mu }\textrm {m}$, where $\epsilon _{d}^+$ is the turbulent dissipation in wall units obtained from the DNS database.

In this study, the fibres consist of Polyamide 6.6 Precision Cut Flock (Flockan) with linear density of $\rho _{l}=9\times 10^{-8}\ \textrm {kg}\ \textrm {m}^{-1}$ (0.9 dtex). The density and cutting length are $\rho =1.15\times 10^{3}\ \textrm {kg}\ \textrm {m}^{-3}$ and $L_{f}=1.2$ mm, respectively, corresponding to a diameter $d_{f}=\sqrt {4 \rho _{l}/(\rho {\rm \pi})} \approx 10\ \mathrm {\mu }\text {m}$. In figure 2, we present a microscopic view of the fibres considered in this study. This observation is important because we used this initially qualitative view to categorise the shape of the fibres in a systematic way. In figure 2(a), we show a raw image of a large quantity of the fibres in dry condition. Fibres are very elongated and characterised by a large value of anisotropy ratio $\lambda =L_{f}/d_{f}\approx 120$ and in addition they are characterised by a small curvature. In figure 2(b), we show a limited number of fibres on a white horizontal background. In this view, we can better appreciate the curvature and also, more importantly, we can appreciate that all fibres are planar. Finally, from the close-up view of figure 2(c), fibres seem to present no inflection point. Observing many samples like the ones presented in figure 2 led us to hypothesise that fibres can be described by a second-order polynomial curve. This point together with the methodology used to detect and model the fibres are further discussed in § 3.2. Relative length and diameter of the fibres to the length scales of the flow, $L_{f}/l_{\eta }$, $L_{f}/\delta$, $d_{f}/l_{\eta }$ and $d_{f}/\delta$, are equal to 2.38, 10.58, 0.02 and 0.09, respectively.

Figure 2. Fibre samples. (a) Raw image of a cluster of fibres (microscope view). (b,c) Close-up view of fibres characterised by different shapes, mainly non-axisymmetric.

The dimensionless parameter used to characterise the behaviour of particles transported by the flow is the particle Stokes number, ${\textit {St}}$, which quantifies the ratio between the particle relaxation time, $\tau _{f}$, and the viscous time scale, $\tau$. To estimate the translational relaxation time of the fibres, we use the relaxation time of randomly oriented prolate spheroids. We considered the relation proposed by Bernstein & Shapiro (Reference Bernstein and Shapiro1994), which gives

(2.1)\begin{equation} \tau_f=\frac{\rho d^{2}}{18\mu}\frac{\lambda \ln \left(\lambda +\sqrt{\lambda^{2}-1}\right)}{\sqrt{\lambda^{2}-1}} { ,} \end{equation}

where $d$, in the case of anisotropic and axisymmetric particles, is the diameter perpendicular to the symmetry axis. Although fibres used in the present study are not exactly prolate spheroids, (2.1) can provide a good approximation of their relaxation time. The $\tau _{f}$ computed as in (2.1) is based on the relaxation time of a spherical particle $(\rho d^{2}/18\mu )$, and corrected for prolate spheroids as function of the fibre aspect ratio, $\lambda =L_{f}/d_{f}$. In the present study, the relaxation time of the fibres is $\tau _{f}=3.5\ \mathrm {\mu }\textrm {s}$, corresponding to ${\textit {St}}=0.003$. In the centre of channel, the Kolmogorov time scale should be used to estimate the Stokes number rather than viscous time scale. As a result, the particle Stokes number based on the Kolmogorov time scale at the channel centre is $1.54\times 10^{-4}$. We observe that in both cases the Stokes number is small enough to neglect any possible inertial effect.

In the following, we provide an estimate of the maximum deformation that fibres can experience. To this aim, we assume a simplified flow configuration in which a straight fibre is cylindrical, blocked at one end and free to move at the other end (cantilever beam). For simplicity, we consider the flow as uniform, perpendicular to the fibre axis and characterised by a velocity $u_\tau$. We choose this penalising configuration to show that, also in the presence of critical conditions, the deformation experienced by the fibre is negligible, and that fibres can be considered as rigid objects. We assume that the fibre Young's modulus is $E=2.5$ GPa (i.e. half of that measured for fibres having a diameter of $20\ \mathrm {\mu }\textrm {m}$; Bunsell (Reference Bunsell2001)). The Reynolds number of the fibre $Re_f=u_\tau d_f/\nu \approx 0.09$ gives a drag coefficient $C_D=66.1$ (Tang et al. Reference Tang, Tian, Yan and Yuan2014). As a result, the force acting on the fibre is $F_D=C_D\rho u^2_\tau L_f d_f /2=4.1\times 10^{-8}$ N. The maximum fibre deformation is computed with the Euler–Bernoulli theory for beams as

(2.2)\begin{equation} w_M=\frac{qL_f^4}{8EI}=7.2\times10^{{-}3}\ \mathrm{mm}, \end{equation}

where $I={\rm \pi} d_f^4/64$ and $q=F_D/L_f$ is the hydrodynamic force per unit of fibre length, which we assume to be uniformly distributed along the fibre. The maximum value of deformation obtained is sufficiently small ($w_M/L_f=0.6\,\%$) to consider fibres as rigid bodies. However, longer and more flexible fibres can exhibit large deformations, potentially producing flow modifications due to an intermittent storage/exchange of energy with the fluid (Allende, Henry & Bec Reference Allende, Henry and Bec2018).

2.3. Three-dimensional imaging

The measurement is carried out in correspondence with the test section, located 8.5 m (${\approx }200h$) downstream of the channel entrance, to ensure the fully developed flow condition. The measurement volume ($53.4\ \textrm {mm}\times 53.4\ \textrm {mm}\times 14\ \textrm {mm}$) is located at the mid-span of the channel. A close-up view of the test section is provided in figure 1(b). Illumination comes from the bottom and consists of a thick laser sheet (527 nm, double cavity, 25 mJ per pulse, Litron LD60-532 PIV). The images are recorded using four Phantom VEO 340 L cameras with sensor size of $2560\times 1600$ pixels at 0.8 kHz and each pixel size is $10\times 10\ \mathrm {\mu }\textrm {m}^2$. The cameras are located on both sides of the channel and in linear configuration. Side and front views of the measurement volume are depicted in figure 1(c). Camera holders are equipped with dampers to remove any possible vibration coming from the channel frame. In order to increase the accuracy of the three-dimensional reconstruction process, we placed the cameras with angles of $35^\circ$ and $30^\circ$ with respect to the spanwise axis of the channel. To minimise the optical astigmatism, we used four prisms filled with water at the side walls of the channel. Finally, the cameras are equipped with Scheimpflug adapters and objective lenses with focal length $f = 100$ mm.

Data acquisition has been performed using three different recording settings for unladen and fibre-laden experiments. The reason behind this choice is the high temporal resolution that fibre-laden experiments require to accurately measure the rotation rate. We used double-frame mode with 3.5 ms time delay for laser pulses for the image acquisition of tomographic particle image velocimetry (tomo-PIV) in the unladen flow. In addition to double-frame recording, to perform 3D-PTV velocimetry in the unladen flow, we recorded single-frame images at 1 kHz acquisition rate. Flow was seeded with tracers, with a diameter of $20\ \mathrm {\mu }\textrm {m}$, by providing particle-per-pixel concentrations of 0.035 and 0.02 for tomo-PIV and 3D-PTV recordings, respectively (see § 2.4 for further details). Source density number of the recordings, $N_{s}$, which quantifies the total number of pixels occupied by the tracers (for further details, see Scarano (Reference Scarano2012)), is equal to 0.44 for tomo-PIV and 0.25 for 3D-PTV, which fall within the limits recommended by Novara & Scarano (Reference Novara and Scarano2012). In the case of fibre-laden experiments, images have been recorded at 1.8 kHz in single-frame mode, to ensure that the displacement of fibres in the centre of the channel cannot exceed 2 pixels. In this way, the measurements are well resolved in time and the accuracy of the tracking process is higher. Source density number $N_{s}$ in this case is equal to 0.1. Focal length, aperture size and depth of focus were the same for both unladen and fibre-laden recordings and were 100 mm, $f/22$ and 31 mm, respectively (table 2). As a result, the digital resolution of the images is $24.1\ \textrm {pixels}\ \textrm {mm}^{-1}$. The camera sensor size was cropped down to $1280\times 1280$ pixels. Illumination was obtained with the simultaneous emission of both laser cavities.

Table 2. Summary of the camera and laser recording parameters adopted.

Prior to reconstruction of the measurement volume, raw images were preprocessed using time and spatial filters. The first step of image preprocessing consists of removing the background noise by subtracting the minimum intensity value of the dataset from each image. Afterwards, a spatial filter is applied to the images by subtracting the minimum intensity within a kernel of five pixels from each pixel. Finally, the intensities were normalised by the average intensity within a kernel of 300 pixels. These steps were essential for increasing the signal-to-noise ratio of the images and for improving the quality of the reconstruction process. A three-dimensional calibration target with size of $58\ \textrm {mm}\times 58\ \textrm {mm}$ was used to map the coordinate system of the illuminated volume on the image. Afterwards, a third-order polynomial function was used for the mapping process. Initial standard deviation of the calibration fit was in the scale of 0.3 pixels, which eventually reduced to values smaller than 0.03 pixels (averaged on all camera views) by applying the volume self-calibration (VSC) algorithm (Wieneke Reference Wieneke2008). The VSC was done by assuming $8\times 8\times 5$ ($x,y,z$) subvolumes and resulted in an average disparity error of approximately 0.02 pixels, which is five times smaller than the recommended threshold for VSC accuracy (Wieneke Reference Wieneke2008). In order to implement the VSC, flow must be seeded with spherical tracers. The multiplicative algebraic reconstruction technique (MART) (Elsinga et al. Reference Elsinga, Scarano, Wieneke and van Oudheusden2006) was used to reconstruct the three-dimensional distribution of light intensity from two-dimensional images of tracer particles and fibres. Since in this study we used MART to reconstruct both unladen and fibre-laden flows and the VSC process was a main step of the calibration to be done before MART, we seeded the water with tracers prior to dispersing the fibres into the water. An example of a raw image of fibre-laden flow containing both fibres and tracer is shown in figure 3. Each snapshot of fibre-laden recording contains, on average, approximately 1000 fibres and the corresponding volume fraction and concentration are $O(10^{-6})$ and $0.025\ \textrm {mm}^{-3}$, respectively. Therefore, it is reasonable to consider that the one-way coupling assumption holds. All processes of image acquisition and single-phase velocimetry have been carried out using Davis (LaVision GmbH).

Figure 3. (a) Example of raw image referring to a portion of the domain. Curved fibres as well as tracer particles can be identified. (b) Close-up view of a group of fibres. The resolution adopted is sufficient to properly characterise the fibres, which consist of tens of pixels.

2.4. Unladen flow velocimetry

The velocimetry of the unladen flow is carried out using both tomo-PIV (Elsinga et al. Reference Elsinga, Scarano, Wieneke and van Oudheusden2006) and shake-the-box (STB) algorithms (Schanz, Gesemann & Schröder Reference Schanz, Gesemann and Schröder2016). The cross-correlation process was applied to interrogation volumes of $48\times 48\times 48$ voxels. Prior to using the STB method, optical transfer function was applied to correct the shape of particles by fitting an elliptical Gaussian model to each subvolume of the VSC. In total, $3\times 10^4$ tracks in each snapshot were detected by the STB process. To evaluate the properties of the fluid flow considered, we compared single-phase measurements with direct numerical simulations of channel flow at $\textit {Re}_{\tau }=350$. Simulations are based on an in-house pseudo-spectral solver (Fourier–Chebyshev discretisation) (Zonta, Marchioli & Soldati Reference Zonta, Marchioli and Soldati2012). The size of the channel is $4{\rm \pi} h \times 2 h \times 2{\rm \pi} h$ and the domain is discretised with $512\times 513\times 512$ collocation points, in directions $x$, $y$ and $z$, respectively, with the lower wall located at $y=0$. Statistics are computed over a time window of $1500\tau ^{+}$. The mean velocity profile (streamwise) obtained from 3D-PTV (STB) and tomo-PIV is compared with direct numerical simulation results at $\textit {Re}_{\tau }=350$ in figure 4.

Figure 4. Mean velocity profile obtained from 3D-PTV (STB; circles) and tomo-PIV (triangles) compared with direct numerical simulation (DNS) at $\textit {Re}_{\tau }=350$ (solid line).

3.1. Phase discrimination

The process of fibre discrimination is used to distinguish the fibres from the tracers and other spurious, reconstructed objects, and consists of a combination MART and volumetric masking. An example of the discrimination process is shown in figure 5. First, the three-dimensional light intensity distribution, consisting of normalised intensities (i.e. intensity has values from 0 to 1), is obtained from the MART reconstruction process. The three-dimensional matrix of light intensities is binarised (figure 5a), according to a threshold value set to 0.05. All the groups of contiguous voxels with unitary value are identified as a cluster. Then, an effective length of the cluster $L_{eff}$, defined in Appendix A, is computed. Finally, clusters with effective length in the range $20<L_{eff}<40$ voxels (red voxels in figure 5(a)) are identified as fibres, and all remaining clusters (blue voxels in figure 5(a)) are removed. The above-mentioned range for the effective length is set by considering the fibre size. By this masking, the majority of the tracers are removed and only large clusters of voxels remain (figure 5b), which mostly represent the real fibres. In some unlikely cases, these clusters may still consist of spurious objects. However, they do not persist over long time periods and can be eliminated by removing the clusters tracked over a short number of snapshots.

Figure 5. (a) Three-dimensional light intensity distribution is obtained using MART (Elsinga et al. Reference Elsinga, Scarano, Wieneke and van Oudheusden2006), and corresponding voxels are shown. (b) After masking, fibres (red voxels) are discriminated from the other objects, e.g. tracers, noise and ghost particles (blue voxels). (c) Close-up view of a small portion of the domain (size is reported). We observe that, although fibres are characterised by a complex shape, they are well captured by the reconstruction and discrimination processes proposed here.

3.2. Fibre modelling

To quantify the fibre concentration, orientation and rotation rate, after discrimination, each fibre has to be associated with the representing coordinates in the three-dimensional space. To this aim, we developed a physically grounded geometrical model for the fibres. We consider a rigid and non-axisymmetric fibre of length $L_{f}$ and we assume that the fibres are bent but not twisted. This hypothesis is motivated by observations, and represents the ground of the modelling process proposed. As a consequence, one can show that the fibre lies on a plane, i.e. it can always exist in at least one plane, $\varPi$, in the three-dimensional space, $(x,y,z)$, that contains the fibre. An example of voxel distribution, discriminated as in § 3.1, is sketched in figure 6(a), where the colour of the voxels refers to the reconstructed light intensity. The geometrical description of the fibre (red line in figure 6a) is obtained through a process of modelling, consisting of three main steps:

1. (i) Preliminary determination of the fibre orientation: we consider the cluster of voxels identified as a fibre in the discrimination process. We consider the coordinates of the voxels located at two ends of the fibres and then find the distance between these two points. The direction of the laboratory reference frame $(x,y$ or $z)$ along which this difference is maximum is preliminarily considered as the orientation of the fibre. In figure 6(a), the fibre orientation is $x$, and we define $x$ as the preliminary ‘fibre direction’.

2. (ii) Identification of the fibre cross-section centres: we consider the light intensities of the voxels defining the fibre. We group the voxels according to the planes perpendicular to the fibre direction. Therefore, each plane represents (approximately) a cross-section of the fibre. We determine the centre of each cross-section as the averaged voxel coordinate ($x,y,z$) weighted on the light intensity of the voxels. In the fibre shown in figure 6(a), the centres of the cross-sections, $(y,z)$ planes, are found. These centres are explicitly indicated as red stars (figure 6a).

3. (iii) Definition of the fibre major axis: finally, the fibre axis is defined as the best fit of the centres defined above. To this aim, we define the arc length coordinate $s$, with origin and end in the first and last cross-sectional centres, so that $0\leqslant s \leqslant L_{f}$. To identify the fibre position in space, for each direction $x_{i}$ (where $x_{i}$ stands for $x$, $y$ or $z$), we find the function $f_{x_{i}}$ that best fits in a least-square sense the coordinates of the centres. In this way, the functions $f_{x_{i}}$ required to approximate the fibre coordinate $x_{i}$ as a function of the arc length coordinate $s$ are obtained (figure 6b–d).

Figure 6. (a) Example of fibre reconstruction (red curve) obtained from light intensity distribution. Voxels, here represented as cubes, are coloured according to their light intensity, from lower (white) to higher (black). The laboratory reference frame ($x,y,z$, blue vectors) is shown, as well as the origin and direction of the arc length coordinate $s$ (green vector), which is used to perform the reconstruction. (b–d) Coordinates of the voxels belonging to the fibres are approximated by three functions ($\,f_{x},\,f_{y},\,f_{z}$) obtained by fitting the coordinates of the centres, as defined in § 3.2 (red stars in a), as a function of the curvilinear coordinate $s$.

In particular, for the present case we set the functions $f_{x_{i}}$ to be second-order polynomials, so that

(3.1)\begin{equation} f_{x_{i}}=a_{i}s^{2}+b_{i}s+c_{i} { .} \end{equation}

One can show analytically that this assumption is consistent with the initial hypothesis that the fibre is contained on a plane. This assumption is also consistent with direct observations of the fibres (see § 2). Indeed, in figure 2(b,c) fibres seem planar and without any inflection point.

The fibre coordinates $f_{x_{i}}$ can be written in matrix form as

(3.2)\begin{equation} {\boldsymbol{x}}_{f}= \left[\begin{array}{@{}c@{}} f_{x} \\ f_{y} \\ f_{z} \end{array} \right] = \left[\begin{array}{@{}ccc@{}} a_{1} & b_{1} & c_{1} \\ a_{2} & b_{2} & c_{2} \\ a_{3} & b_{3} & c_{3} \end{array} \right]\left[ \begin{array}{@{}c@{}} s^{2} \\ s \\ 1 \end{array} \right]= {\boldsymbol{As}} { ,} \end{equation}

where ${\boldsymbol {x}}_{f}$ is the approximated fibre coordinate vector, ${\boldsymbol {A}}$ is the matrix of the coefficients ($a_{i}, b_{i}, c_{i}$) and ${\boldsymbol {s}}$ contains the arc length coordinate vector. Therefore, the modelled fibre is fully defined by the matrix ${\boldsymbol {A}}$ and the length $L_f$. An example of the reconstruction process performed for fibres of different shape is shown in figure 7. In particular, we observe in figure 7(a,b) that the fibres (left, red objects taken from microscope images) are well fitted by second-order polynomials (right, black objects obtained from fitting).

Figure 7. Fibre samples. (a–c) Three different classes of fibres, classified according to their curvature, are shown. The fibres (left, red objects taken from microscope images) are well fitted by the second-order polynomials (right, black objects obtained from fitting). This assumption is required to employ the method proposed here.

The proposed fitting method is based on the assumption that the fibre is a parabolic segment. However, even in cases for which fibres are not precisely parabolic segments, like the case shown in figure 7(c), in which fibre curvature exhibits strong gradients, the proposed fitting method supplies a reasonably accurate approximation for the shape of the real fibre.

The next step required for fibre tracking consists of identifying the fibre centre of mass and orientation. We consider now the fibre sketched in red in figure 8(a). The projection of the fibre on the reference planes is shown (blue lines) as well as the centre of mass of the fibre ${\boldsymbol { G}}=(x_{G},y_{G},z_{G})$, where

(3.3)\begin{equation} x_{i,G}=\frac{1}{L_{f}}\int_{0}^{L_{f}}x_{i}(s)\,\text{d}s { ,} \end{equation}

where $x_{i}$ stands for $x$, $y$ or $z$. The plane $\varPi$ containing the fibre is defined by the equation

(3.4)\begin{equation} {\boldsymbol{n}}\boldsymbol{\cdot}\left[{\boldsymbol{e}_{\boldsymbol{1}}}(x-x_{G}) + {\boldsymbol{e}_{\boldsymbol{2}}}(y-y_{G}) + {\boldsymbol{e}_{\boldsymbol{3}}}(z-z_{G})\right] = 0 { ,} \end{equation}

where ${\boldsymbol {e}_{\boldsymbol {i}}}$ are the unit vectors of the laboratory reference frame and ${\boldsymbol {n}}$ is the unit vector perpendicular to $\varPi$. Given three points of the fibre (${\boldsymbol {A}}$, ${\boldsymbol {B}}$ and ${\boldsymbol {C}}$), ${\boldsymbol {n}}$ is determined as

(3.5)\begin{equation} {\boldsymbol{ n}}=\left[\begin{array}{@{}c@{}} (y_{B} -y_{A})(z_{C} -z_{A}) - (z_{B} -z_{A})(y_{C} -y_{A})\\ (x_{C} -x_{A})(z_{B} -z_{A}) - (x_{B} -x_{A})(z_{C} -z_{A})\\ (x_{B} -x_{A})(y_{C} -y_{A}) - (y_{B} -y_{A})(x_{C} -x_{A}) \end{array} \right]. \end{equation}

Following Voth & Soldati (Reference Voth and Soldati2017), we define the fibre reference frame using the inertia tensor

(3.6)\begin{equation} {\boldsymbol{I}}_{ij}=\rho_{l}\int_{0}^{L_{f}}\left[ (\,f_{x_{i}}-x_{i,G})^{2}\delta_{ij}-(\,f_{x_{i}}-x_{i,G})(\,f_{x_{j}}-x_{j,G}) \right] \text{d}s, \end{equation}

with $\rho _{l}\ (\textrm {kg}\ \textrm {m}^{-1})$ the linear density of the fibres and $\delta _{ij}$ the Kronecker delta. Therefore, we align the reference frame of the fibre ($O'x'y'z'$) with the normalised eigenvectors of ${\boldsymbol { I}}$. Note that the eigenvalues of ${\boldsymbol { I}}$ are real and positive and correspond to the principal inertia moments of the fibre, $I_{1}$, $I_{2}$ and $I_{3}$. In the present case, one eigenvalue is much smaller than the other two and we align $x'$ with the corresponding eigenvector. Similarly, $y'$ and $z'$ are aligned with the second and third eigenvector, respectively. When the fibre is curved, $x'$ and $z'$ belong to $\varPi$ whereas $y'$ is aligned with $\boldsymbol {n}$.

Figure 8. (a) Non-axisymmetric fibre (red line) lying on the plane $\varPi$. The inertial frame of reference, with axes labelled as $x$, $y$ and $z$, remains fixed in space and time. The fibre frame of reference, centred in the fibre midpoint located at $s=L_{f}/2$ ($O'$, red bullet), has axes ($x',y',z'$) aligned with the principal directions of the inertia tensor. The projection of the fibre on the three planes is also shown (blue lines). Note that, in general, the centre of mass of the fibre ($G$, cyan bullet) may be external to the fibre. (b) Angles defined between the reference frame of the fibre ($O'x'y'z'$) and the reference frame of the laboratory translated to the midpoint $O'$ ($O''x''y''z''$).

Three angles $(\vartheta _{x},\vartheta _{y},\vartheta _{z})$ define the relative orientation of the fibre reference frame ($O'x'y'z'$) with respect to the laboratory reference frame translated to the midpoint of the fibre $(O''x''y''z'')$. The system is represented in figure 8(b). Three rotations (and the corresponding rotation matrices) are required to identify the orientation of the fibre with respect to the laboratory reference frame. To this aim, we use the quaternions formulation (Lecrivain et al. Reference Lecrivain, Grein, Yamamoto, Hampel and Taniguchi2020). We consider the unit vectors of the reference frame $O'x'y'z'$ and $O''x'' y''z''$, respectively $\boldsymbol {e_{1}'},\boldsymbol {e_{2}'},\boldsymbol {e_{3}'}$ and $\boldsymbol {e_{1}''},\boldsymbol {e_{2}''},\boldsymbol {e_{3}''}$. The angle $\vartheta _{x}$ is defined here as the angle required to align $\boldsymbol {e_{1}''}$ with $\boldsymbol {e_{1}'}$. We compute the unit quaternion $\boldsymbol {q}$ as

(3.7)\begin{equation} {\boldsymbol{ q}}=\left[ \begin{array}{@{}c@{}} q_{s}\\ q_{x}\\ q_{y}\\ q_{z} \end{array} \right]= \frac{1}{\sqrt{(q_{s}^*)^{2}+(q_{x}^*)^{2}+(q_{y}^*)^{2}+(q_{z}^*)^{2}}} \left[\begin{array}{@{}c@{}} q_{s}^{*}\\ q_{x}^{*}\\ q_{y}^{*}\\ q_{z}^{*} \end{array} \right], \end{equation}

with $q_{s}^{*}=1+\boldsymbol {e_{1}''}\boldsymbol {\cdot }\boldsymbol {e_{1}'}$ and $[q_{x}^{*}\ q_{y}^{*}\ q_{z}^{*}]^{T}=\boldsymbol {e_{1}''}\times \boldsymbol {e_{1}'}$. The rotation matrix associated with the quaternion $\boldsymbol {q}$ is

(3.8)\begin{equation} {\boldsymbol{ R}}_{\vartheta_{x}}=\left[ \begin{array}{@{}ccc@{}} 1/2-q_{y}^{2}-q_{z}^{2} & q_{x}q_{y}-q_{s}q_{z} & q_{x}q_{z}+q_{s}q_{y}\\ q_{x}q_{y}+q_{s}q_{z} & 1/2-q_{x}^{2}-q_{z}^{2} & q_{y}q_{z}-q_{s}q_{x}\\ q_{x}q_{z}-q_{s}q_{y} & q_{y}q_{z}+q_{s}q_{x} & 1/2-q_{x}^{2}-q_{y}^{2} \end{array} \right], \end{equation}

and we have that $\boldsymbol {e_{1}''}={\boldsymbol { R}}_{\vartheta _{x}}\boldsymbol {e_{1}'}$. The rotation angle is finally determined as

(3.9)\begin{equation} \vartheta_{x}=2\text{atan2}\left(\sqrt{q_x^2+q_y^2+q_z^2},q_{s}\right). \end{equation}

Following the same procedure, the two rotation matrices ${\boldsymbol { R}}_{\vartheta _{y}}$, ${\boldsymbol { R}}_{\vartheta _{z}}$ and the corresponding angles are determined.

3.3. Curvature

The model adopted to describe the fibre, as discussed in § 3.2, makes it lie on the plane containing the fibre, $\varPi$, which is fully determined by the normal vector $\boldsymbol {n}$. The coordinates of the fibre can be expressed with respect to a specific reference frame so that the two axes ($x',y'$) lie on $\varPi$ and the third ($z'$) axis corresponds to $\boldsymbol {n}$. As a result, the coordinates of the fibre with respect to this reference frame are

(3.10)\begin{equation} {\boldsymbol{ x}}_{f}'= \left[ \begin{array}{@{}c@{}} f_{x'} \\ f_{y'} \\ f_{z'} \end{array} \right]= \left[ \begin{array}{@{}ccc@{}} a_{1}' & b_{1}' & c_{1}' \\ a_{2}' & b_{2}' & c_{2}' \\ 0 & 0 & 0 \end{array} \right] \left[\begin{array}{@{}c@{}} s^{2} \\ s \\ 1 \end{array} \right], \end{equation}

consisting of the projection of the parametric curve defined by (3.2), with $a_{i}',b_{i}',c_{i}'$ suitable coefficients (these coefficients are obtained applying an appropriate rotation ${\boldsymbol {R}}$ to the matrix of coefficients ${\boldsymbol {A}}$). The local curvature $\kappa _{l}(s)$ of the two-dimensional parametric function defined in (3.10) is given by

(3.11)\begin{equation} \kappa_{l}(s)=\frac{\,f_{x'}'\,f_{y'}''-\,f_{x'}''\,f_{y'}'}{\left[\left(\,f_{x'}'\right)^{2}+\left(\,f_{y'}'\right)^{2}\right]^{3/2}}{ ,} \end{equation}

where the symbols $'$ and $''$ indicate the first and second derivative with respect to the coordinate $s$. Therefore, using (3.10), the local curvature reads

(3.12)\begin{equation} \kappa_{l}(s)=\frac{2(a'_{2}b'_{1}-a'_{1}b'_{2})}{\left[\left(2a_{1}'s+b_{1}'\right)^{2}+\left(2a_{2}'s+b_{2}'\right)^{2}\right]^{3/2}}{ ,} \end{equation}

and the unit vectors locally tangent ${\boldsymbol {T}}(s)$ and normal ${\boldsymbol {N}}(s)$ to the fibre in the reference frame of the plane are (see figure 9)

(3.13a,b)\begin{equation} {\boldsymbol{T}}(s)=\left[ \begin{array}{@{}c@{}} 2a_{1}' s + b_{1}' \\ 2a_{2}' s + b_{2}'\\ 0 \end{array} \right] {,}\quad {\boldsymbol{N}}(s)= \frac{1}{\kappa_{l}(s)}\left[ \begin{array}{@{}c@{}} 2a_{1}'\\ 2a_{2}'\\ 0 \end{array} \right] { .} \end{equation}

Figure 9. Projection of a fibre on the plane $\varPi$. The unit vectors normal ${\boldsymbol {N}}(s)$ and tangent ${\boldsymbol {T}}(s)$ at the midpoint of the fibre ($s=L_{f}/2$) are also shown. The normal vectors (blue) are proportional to the local curvature $\kappa _{l}$.

In the following, we characterise the behaviour of the fibres according to their mean curvature, defined here as

(3.14)\begin{equation} \kappa=\frac{1}{L_{f}}\int_{0}^{L_{f}}|\kappa_{l}(s)|\,\text{d}s{ .} \end{equation}

We estimate the length of the fibre by computing the p.d.f. of the length of all fibres tracked in our experiments (figure 10a). The representative fibre length is chosen by referring to the peak of the p.d.f. corresponding to $\overline {L_{f}}=1.26$ mm, which is slightly greater than the mean length of the fibres based on manufactured nominal length (1.2 mm), perhaps due to the accuracy of the cutting process. The mean curvature $\kappa$ is normalised by $\kappa _0$, which is calculated by considering the curvature of an arc of a half-circle with length equal to the mean length of the fibres, i.e. $\kappa _0= {\rm \pi}/\overline {L_{f}}=2.53\ \textrm {mm}^{-1}$. Finally, fibres are classified according to their dimensionless curvature $\kappa ^*=\kappa /\kappa _0$ so that straight fibres correspond to $\kappa ^{*}=0$ and semicircumference-shaped fibres to $\kappa ^{*}=1$. The p.d.f. of $\kappa ^*$ of all fibres tracked in the experiments is reported in figure 10(b). We observe that the fibres used in this study are far from being considered as straight. In order to be able to characterise their behaviour as a function of their curvature, we arbitrarily divided the dataset into different classes consisting of ranges of curvature. By this classification, we analyse the effect of curvature on the main dynamics of the fibres.

Figure 10. The p.d.f. of length (a) and normalised curvature (b) of the fibres reconstructed in this study. Most probable fibre length measured corresponds to 1.26 mm, close to the nominal cutting value ($L_{f}=1.2$ mm). Most probable fibre shape corresponds to the normalised curvature value $\kappa ^{*}=0.31$.

3.4. Tracking

The tracking process consists of the identification of the same fibre in two consecutive frames. After fibre discrimination, reconstruction and modelling, the centre of mass of the fibre ($x_{G},y_{G},z_{G}$) is identified in the first instant. In the subsequent instant, the presence of the centre of mass of a fibre within a distance of 5 voxels from the previous one is searched. The threshold radius of 5 voxels is set according to the estimated flow velocity. If a centre of mass is found within this range, the fibre in two consecutive frames is tracked. The behaviour of a single fibre is shown in figure 11. The measured position of the centre of mass (symbols in figure 11(a–c)) experiences fluctuations in all directions. However, the spanwise and wall-normal components are more affected due to the short displacement between two consecutive snapshots. This effect is even more pronounced in the instance of the fibre orientation angles, $\vartheta _{x},\vartheta _{y},\vartheta _{z}$ (symbols in figure 11(d–f)). Since these fluctuations have negative effects on the calculation of the velocity components, location and orientation of the fibres are filtered in time using a second-order polynomial. This filter is sufficient to capture the fibre motion and to reduce the noise from the experimental measurements (Rowin & Ghaemi Reference Rowin and Ghaemi2019). The window size of the filter is set to 28 ms (or approximately $2.8\tau ^+$) and only fibres tracked longer than this time window are considered for the statistics. Finally, the time derivatives of the filtered quantities are obtained from the coefficients of the polynomials. The effect of the time filtering is shown in figure 11 (red lines).

Figure 11. Trajectory of (a–c) the centre of mass ($x_{G},y_{G},z_{G}$) and (d–f) fibre orientation ($\vartheta _x,\vartheta _z,\vartheta _{y}$) of the fibre with respect to the snapshot number. Data measurements (grey symbols) are well resolved in time (see insets), and are filtered in time using a second-order polynomial (red lines).

3.5. Tumbling and spinning rates

In the case of axisymmetric particles, rotation rates are decomposed into a component along the symmetry axis, called spinning, and two components perpendicular to the symmetry axis, defined as tumbling (Voth & Soldati Reference Voth and Soldati2017). To compute the angular velocities required to identify spinning and tumbling rates, a different set of angles is used compared with that introduced in § 3.2. In particular, we use the Euler angles corresponding to a specific rotation matrix. The columns of this matrix are the eigenvectors of the inertia tensor. We consider the reference frame of the fibre $(O'x'y'z')$ indicated in figure 8(b): with the Euler angles, three angular velocities can be computed, $\omega _{x}$, $\omega _{y}$ and $\omega _{z}$, which are aligned with the axes $x'$, $y'$ and $z'$, respectively.

Following Voth & Soldati (Reference Voth and Soldati2017), we define the solid body rotation rate $\boldsymbol {\varOmega }=\boldsymbol {\omega }_{x}+\boldsymbol {\omega }_{y}+\boldsymbol {\omega }_{z}$. In the instance of axisymmetric particles, a unit vector $\boldsymbol {p}$ aligned with the symmetry axis is used to define the spinning and tumbling rates. In our case, since in general the fibre is non-axisymmetric, we arbitrarily align $\boldsymbol {p}$ with $x'$. We can rewrite the solid body rotation in terms of squared spinning ($\boldsymbol {\varOmega }_{s}$) and squared tumbling ($\boldsymbol {\varOmega }_{t}$) components, so that $\boldsymbol {\varOmega }=\boldsymbol {\varOmega }_{s}+\boldsymbol {\varOmega }_{t}$, where

(3.15a,b)\begin{equation} \boldsymbol{\varOmega}_{\boldsymbol{s}}=(\boldsymbol{\varOmega}\boldsymbol{\cdot}\boldsymbol{p})\boldsymbol{p}= \omega_{x}\boldsymbol{p}\quad\text{and}\quad \boldsymbol{\varOmega}_{t}=\boldsymbol{\varOmega}\times\boldsymbol{p}{.} \end{equation}

As a result, one can show that $\varOmega _{t}\varOmega _{t}=(\boldsymbol {\varOmega }_{t}\boldsymbol {\cdot } \boldsymbol {\varOmega }_{t})=(\omega ^{2}_{y}+\omega ^{2}_{z})$. The temporal filter introduced in § 3.4 is adopted here as well.