Models of hydrodynamic flow in the bowhead whale filter feeding apparatus
Department of Biology, Hampden-Sydney College, Hampden-Sydney, VA 23943, USA
e-mail: awerth{at}hsc.edu
Accepted 14 July 2004
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Summary |
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Key words: bowhead whale, Balaena mysticetus, water flow, buccal cavity, baleen, tongue, feeding mechanism, morphology, filtration, flow, hydrodynamics
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Introduction |
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Just as the elastic gular pleats, loose mandibular joint and flaccid,
deformable tongue of rorquals reflect their lunge feeding, balaenid oral
morphology is well designed for continuous sieving of microscopic prey
(Fig. 1). The subrostral gap (a
cleft between baleen racks below the tip of the rostrum) and orolabial sulcus
(a gutter-like depression medial to the lip), which are specific features of
the balaenid oral cavity designed exclusively to promote continuous,
unidirectional water flow, are singular among mysticetes, as are the
exceptionally long (up to 4 m), springy, finely fringed baleen (3570
fringes m2), fused cervical vertebrae, firm tongue and high
semicircular lips, extending well above the mandibles to enfold the narrow,
arched rostrum (Werth,
2001).
Based on their description of the gross and microscopic structure of
bowhead whale Balaena mysticetus baleen, Lambertsen et al.
(1989) suggested that the
filtration mechanism of balaenid feeding is powered not merely by hydraulic
but also by hydrodynamic pressures. Their photogrammetric study documented the
ability of the lower jaw and lip to rotate outward during feeding, creating a
distinct channel for water flow along the outside of the baleen, which, when
coupled with the convex lateral profile of the baleen rack, could cause lower
pressures to develop outside the baleen, thereby drawing water from the buccal
cavity through the sieve to improve filtering efficiency while also
eliminating a compressive bow wave in front of the mouth.
Numerous restrictions (legal, logistical, fiscal, etc.) prevent direct
experimentation on bowhead filter feeding; even close observation of feeding
is now precluded by limited physical approach to live whales. However,
observing bowhead feeding from a kayak, Otto Fabricius reported in 1780 that
planktonic prey seemed to move into the whale's mouth as if attracted to it.
In his monograph on Greenland fauna
(Fabricius, 1780), he wrote:
"In this respect must Nature be admired, that these crustaceans find
pleasure in its whalebones, seek there from all directions and go in more or
less by themselves".
Accordingly, a pair of distinct yet complementary morphological models was created to investigate biomechanical aspects of water flow in the bowhead oral cavity during continuous ram filter feeding. A conceptual mathematical model was designed to test and quantify predictions of hydrodynamic effects of flow with steady state hydromechanical conditions. In addition, a 1/15 scale physical model of the bowhead oral cavity (Fig. 2) was constructed to test and better visualize these processes in a flow chamber. Both models rely on morphometric and anatomical data obtained from adult and fetal bowhead whales harvested for subsistence purposes by Inupiat Eskimos near Point Barrow, Alaska, as well as from information concerning bowhead foraging ecology.
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Materials and methods |
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Two principal dimensions (dorsoventral in the mid-sagittal plane, denoted here as vertical; and in the frontal plane, or horizontal) were obtained for the anterior opening of the mouth as well as the mouth's paired posterior openings where filtered seawater exits the oral cavity posterior to the lips (Fig. 3). For the anterior opening, the dorsoventral or vertical (AV) measurement was defined as the distance between the tip of the upper jaw (at the subrostral gap between anteriormost baleen plates) straight down to the floor of the mouth, just at the anterior tongue tip; the anterior frontal or horizontal (AH) measurement was between the lowest points of the anteriormost baleen plates, where they touched the medial sides of the lips as they hung down. Measurements of the posterior mouth openings were defined as follows: posterior horizontal (PH), from the rear of the lip across the orolabial sulcus (the gutter-like depression posterior to the lip) to the head at the level of the eye; posterior vertical (PV), from the bottom of the orolabial sulcus up to the upper jaw, at the approximate midline of the PH dimension. As all measurements were recorded, gape was open to its normal feeding position (approximately 20% of body length), as ascertained from photographs of feeding whales and as judged by (1) AV length relative to Lb and (2) relative disclosure of baleen.
Given the clear landmarks described above, accuracy of measurement (both at the harvest site as well as during later confirmation by analysis of scaled photographs) was assured. Nonetheless, of the eight whales examined for this study, reliable measurements of oral structures and dimensions could be obtained from only five specimens. The other three whales were either turned slightly on their sides during harvesting, so that the lips rotated medially or laterally, or so that the gape was not open to its normal position during feeding, or else key structures were damaged during haulout or harvesting, in all three cases rendering some measurements suspect. Scaling the measurements of all whales to a standard 15 m Lb (using a 14.99 m long whale, 93B6) confirmed that these dimensions naturally scale linearly (almost perfectly isometrically), negating any possible allometric effects that could affect the dimensions and hence the construction of the mathematical or physical models.
Use in constructing models
The paired perpendicular dimensions (horizontal and vertical) of the
anterior and posterior mouth openings were taken, loosely, as diameters for
these roughly circular apertures. Accordingly, the average of both
measurements [(AV+AH)/2] was taken as a mean diameter, from which the
approximate radius of each orifice could be calculated.
Additionally, two fetal bowhead specimens were used in this study (88KK1F, Lb=1.5 m, collected from a 14.9 m female on 9/24/88 at Kaktovik, AK; 90B4F, Lb=3.9 m, from a 14.9 m female on 5/19/90 at Barrow, AK), representing mid-term and near-term gestational stages. Both fetuses were whole-body formalin-perfused through umbilical vessels and delivered from DWM/NSB to the Department of Veterinary Anatomy and Fine Structure, Louisiana State University School of Medicine, where they were examined, measured and dissected. Unfortunately, allometric growth of numerous features (e.g. the rostrum and lip lack the high, curving arch found in adults; baleen does not grow until late in prenatal development) meant that fetal measurements could not be accurately scaled to adult size. Thus no fetal dimensions were used in constructing either the mathematical or physical model. Due to their small size, however, the fetuses still proved quite useful, as several aspects of oral anatomy that do not change shape during prenatal/postnatal growth and that demonstrate isometric growth (e.g. lingual furrow, genioglossal tubercle, orolabial sulcus) could be more closely scrutinized for consideration in assembling the 1/15 scale physical model.
Mathematical model
Rationale and design
As depicted in Fig. 1, the
bowhead's capacious scoop-shaped lower jaw forms a large opening for water
intake, while paired openings at the rear of the mouth (caudal to the
orolabial sulci; Fig. 3) serve
as exhaust ports. The resulting channels, bounded by the lips, baleen and
floor of the mouth, act as oblique, elliptical conduits for water flow,
analogous to a huge, irregular, Y-shaped pipe
(Fig. 4). The pipe-like nature
of this system lends itself to fluid dynamic analysis.
According to basic principles of hydrodynamics, the equation of continuity for fluids (an indirect statement of the law of conservation of mass) demands that the volume flow rate be the same in all parts of a pipe, so that the velocity of flow through sections with smaller cross-sectional area must increase. Bernoulli's theorem (essentially an extension of the law of conservation of energy) states that the sum of the pressure and potential and kinetic energies per unit volume must be constant at all points in streamlined flow, so that as fluid velocity increases, pressure simultaneously decreases.
Analysis
Combining several sources of information, i.e. measurements obtained during
examination of freshly harvested whales, dissection of preserved fetal
specimens, anatomical data concerning tongue and lip positions in
vivo, and behavioral observations (gape, swimming speed and direction), a
simple conceptual model was devised to investigate water flow in the bowhead
oral cavity during continuous surface or mid-water ram filtration. This model
depends on (1) the incurrent flow rate and (2) the diameter(s) of the `pipe'.
Reasonable values for both can easily be found. With this morphological and
ecological information, various equations can be employed to measure the
pressure differential as water flows through the bowhead oral cavity during
filter feeding. All assume non-turbulent, steady state flow of incompressible
fluid.
Given the information on flow velocity
() and cross-sectional areas of the
anterior and posterior openings (AO and PO), the pressure differential
(
P) between the front and back of the mouth can be calculated
by a simplified version of Bernoulli's equation
(Vogel, 1994
):
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Although balaenid oral openings are manifestly non-circular, values for a
pressure differential may be computed via formulae for flow through
circular apertures at high Reynolds numbers (low viscosity, high inertia). A
version of the HagenPoiseuille equation
(Vogel, 1994):
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Finally, a variation of the NavierStokes equation (essentially
F=ma, where F=force, m=mass,
a=acceleration), from Muller et al.
(1982):
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Physical model
Construction
A 1/15 scale model head of an adult (15 m) bowhead whale was fashioned from
air-drying synthetic plastic clay stone over a lightweight armature of wire,
wood and rigid polystyrene foam. Plates of `baleen' were fabricated from
pliable 18 mil high density polyethylene. The model was primed with acrylic
water-based gesso prior to painting with flat spray enamel and sealing with
several coats of clear polyurethane to ensure waterproofing.
The model was designed to replicate all structures of the balaenid oral cavity in proper proportions, positions and relations. The head was constructed in two sections, with an articulating upper and lower jaw, so that although the lips and tongue were immobile, the mouth could be opened and closed. The lips were created to simulate the adducted (laterally rotated) position for feeding at normal gape; the tongue was sculpted in typical elevated mid-sagittal position. Obviously, because the plastic `baleen' was not constructed of the actual keratinous tissue (and since even this tissue would exhibit different physical properties at reduced scale), a material of suitable flexibility (HDPE: high density polyethylene) was chosen to approximate, as well as any simulated material could, the true plates' mechanical behavior and to recreate the exact dimensions of length, width and thickness with regard to scale, as well as the number of plates (300). Unfortunately the fibrous mat of interwoven medial fringes could not be precisely duplicated at this scale, yet the paramount concern was to devise a model demonstrating the specific anatomical features of the baleen sieve (e.g. convex lateral surface) that determine its filtering capability and affect intraoral water flow. Care was taken to reproduce accurately other internal features (e.g. the tongue's central furrow, anterior concavity, longitudinal plicae and genioglossal tubercle). Dimensions of the anterior and posterior oral openings were taken from the measurements obtained during the necropsy procedure from harvested whales and reduced to 1/15 scale.
Testing
The completed 35 cm model (Fig.
2) was placed (suspended on clear monofilament wire) in a 135 l
flow tank (30 cmx30 cmx80 cm; working section with length of 70 cm
and cross-sectional area of 900 cm2; 11.5% blockage due to model),
through which water rapidly recirculated at a rate of roughly 17 l
min1. Brine shrimp Artemia nauplii eggs or other
reflective particles and dyes were introduced to show water flow patterns as
the model was videotaped in lateral, anterior and dorsal views while suspended
before a ruled (1 cm2) grid. Videotaping occurred at distances
(lens to physical model) of 1540 cm; most sequences were shot (and best
spatial resolution was achieved) at a distance of 24 cm. Video sequences were
shot using a Hitachi 1600A standard color VHS videocamera (30 frames per
second; Hitachi Corp, Fremont, CA, USA) and analyzed frame-by-frame using a
Panasonic AG-1730 ProLine Multiplex VCR (Matsushita Electric Corp., Osaka,
Japan). Flow velocity was measured by video analysis of movement of the
reflective particles relative to the ruled background.
Videotaped sequences were analyzed to examine flow patterns in incurrent
and excurrent streams and to calculate their respective flow rates. In some
trials the model was moved through the tank, in both circulating and
non-circulating (stagnant) water, again on the suspension wires, at
=3 cm s1
(Re=1.8x103, with characteristic length
D=30 cm and
=3 cm
s1 in freshwater at 5°C), to duplicate the locomotion
powering ram filtration. For later testing a tube was placed at the rear of
the buccal cavity; suction pressures generated by a water pump or by siphoning
(measured at 7.33 kPa) enabled increased water flow (230% increase,
from 3 cm s1 to 7 cm s1) through the oral
cavity for clearer visualization of filtration and hence of the flow rate and
path of reflective particles or dye.
Direct pressure measurement
Finally, intraoral pressures were directly measured in the 1/15 scale
physical model to assess independently the results derived from the fluid
mathematical model. Two types of pressure transducers were used. A
strain-gauge based DTX Disposable Transducer (4 ms response time; Spectramed,
Oxnard, CA, USA) with a bare 1 mm2 tip oriented perpendicular to
flow was situated (fixed in place and, in earlier preliminary trials, allowed
to dangle) at three locations throughout the buccal cavity: at the rear of the
mouth, on the tongue's median furrow; just posterior to the mouth's anterior
orifice, posterior to the subrostral baleen gap; and in the orolabial sulcus
lateral to the baleen but medial to the lip. Also, a 2F Millar Mikro-Tip®
micromanometer-tipped catheter pressure transducer (20 ms response time;
Millar Instruments, Houston, TX, USA) was used, again with a bare 1
mm2 tip oriented vertically (dorsoventral, perpendicular to flow),
and fixed in the model at the locations noted above, again with the transducer
tip perpendicular to flow in the static (but close to the dynamic) component
of the pressure field. Most pressures were recorded at flow velocity of 3 cm
s1.
DTX transducers were calibrated and linked through ETH-400 transducer amplifiers to a MacLab AD converter (ADInstruments, Milford, MA, USA) and recorded/analyzed at sampling rates of 100 kHz (16 bit resolution digitization) using MacLab software on a Power Macintosh G3 computer (Apple Computers, Cupertino, CA, USA); Millar transducers were connected to the MacLab unit and calibrated via a TCB 500 control unit with recording at the same sampling rate.
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Results |
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Mathematical model
The conceptual mathematical model depends on the bowhead mouth's incurrent
flow rate and the diameter of the oral `pipe'. Regarding the former, although
the speed of migrating bowheads ranges from 39 km h1,
as measured during census tracking by theodolite or surveyor's transit
(Reeves and Leatherwood,
1985), observations of feeding whales in neutral current, open
water conditions (Carroll et al.,
1987
; Lowry, 1993
;
Nowacek et al., 2001
) suggest a
more modest foraging speed (and hence water influx velocity) of 4 km
h1. This speed (4 km h1) was used for
initial calculations of the mathematical model, but a faster foraging speed (6
km h1, the mean of the theodolite records of 39 km
h1) was used in further calculations to test the effect of
incurrent flow velocity.
As for the size of the oral `pipe', published estimates of the oral opening
in Balaena range from 19 m2, yet my necropsy data
conform to values presented by Thomson
(1987). Based on jaw and
baleen measurements and aerial photographs of skim-feeding bowheads, from
which gape and lip position can be clearly seen, Thomson calculated that the
anterior mouth opening (AO, in m2) for whales of body length
(Lb) 718 m can be ascertained by the equation:
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For a 15 m whale this yields a value of 5.73 m2, in line with my calculation of 5.09 m2 for a whale (93B6, hauled out on ice) of similar length and with presumed full gape. For all adult whales used in this study the mean AO was 4.23±0.66 m2 (± S.E.M., N=5). My calculated area for the posterior aperture of a 15 m Lb whale, again from necropsy data, is 1.57 m2 (for all whales, mean Lb 11.9 m: PO=1.39±0.16 m2, N=5), for a total effluent area (with two orifices, one for each lip) of 3.14 m2 in a 15 m whale. I assume these dimensions are similar for whales feeding below the surface in normal upright position (Thomson's study was based in part on aerial photographs of whales feeding at the surface on their sides). Again, this model also assumes non-turbulent, steady-state flow of incompressible fluid. In all of the calculations that follow I use AO and PO areas based solely on my measurements, as shown in Table 1. Dimensions computed from Thomson's regression equation were checked (for accuracy and precision) against my measurements but not used in any mathematical modeling.
Using the values presented above for a 15 m whale(V=4 km h1=1.11 m s1; AO=5.73 m2; PO=3.14 m2), Bernouilli's equation provides a pressure differential of 1026.81 Pa (7.70 mmHg) from the front to the back of the mouth. As noted, Bernoulli's equation holds for non-turbulent flow and the calculated Reynolds number for these conditions (1.25x103) indicates laminar flow. At a higher foraging speed of 6 km h1, Bernouilli's equation yields a pressure differential of 2324 Pa (17.43 mmHg) for this standard 15 m whale. Calculated values for whales of other sizes swimming at both velocities are listed in Table 2.
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The simplified HagenPoiseuille equation 1 (using an orifice
coefficient) yields a pressure of 1768 Pa for a 15 m whale at the 4 km
h1 foraging speed, assuming the oral opening
(AO=r2) is 5.09 m2 (r=1.27 m) and the
volume flow rate, , is 5.65
m3 s1 (volume based on my measurements). The
restatement of the HagenPoiseuille equation 2 using resistance (from
the physical model's `baleen' filter; R=288.14 N
m2) yields a pressure differential of 1628 Pa for the same
conditions. At the higher 6 km h1 foraging speed, again for
a standard 15 m whale, the two forms of this equation, respectively, yield
4002.7 Pa and 2449.3 Pa.Given the potential pulsatile nature of
flow through the baleen mouth, the dimensionless Womersley number,
,
was calculated (based on fluke stroke frequency
=0.3, using data from
Nowacek et al., 2001
,
2003
). This number
(
=3.1x103) shows that flow is not unsteady, validating
use of the HagenPoiseuille equation.
Finally, the NavierStokes equation, using a 3.8 m head length (LH) for the oral cavity of a 15 m Lb whale with 1.11 m s1 flow, yields a pressure drop of 1261.3 Pa. If foraging speed (and hence incurrent flow velocity) increases from 4 to 6 km h1 for the same size whale, then this equation yields a greater negative pressure of 2856 Pa, which is more than twice the value for the slower speed. Values for whales of differing size at both speeds (Table 2) are identical to those of a 15 m whale, since head length (obtained from necropsy data) is almost perfectly proportional to Lb and since the NavierStokes equation deals with fluid acceleration and thus flow velocity.
While the latter pressure values (from the HagenPoiseuille and NavierStokes equations) are derived from equations relating to fluid acceleration through circular apertures, they corroborate the Bernoulli calculation of 1467 Pa and confirm that it is in the proper order of magnitude. All iterations of the mathematical model yield a pressure differential, from the front to the rear of the filtering bowhead's oral cavity, on the order of 1300 Pa for the default scenario of a 15 m whale foraging at 4 km h1. Pressure differentials increase as foraging speed increases, and are generally higher in larger whales, though this depends on the formula(e) used. [As I did not have a 5 m long necropsy specimen to measure, values for that Lb in Table 2 are rough approximated extrapolations based on the 15 m `standard' adult and the near-term 3.9 m fetus, although it is acknowledged that, as mentioned, the latter displays allometric scaling.] All conditions tested in the mathematical modeling reflect laminar flow, fulfilling the assumptions of the formulae.
Physical model
Visualization of flow and filtration
Water flow upstream of the model (again, measured by video analysis of
particle or dye movement) occurred at a velocity of 2.72±0.23 cm
s1 (mean ± S.E.M.,
N=31). Water and particles could be seen entering the mouth at a mean
flow velocity of 3.18±0.39 cm s1 (N=16) and
exiting through the smaller posterior opening(s) at a mean flow velocity of
4.84±0.47 cm s1 (N=16);
Fig. 5B. These rates are
derived from flow through a stationary model. However, forward movement of the
physical model (at 3 cm s1) through neutral current
conditions yielded similar flow velocities. When scaled to full size this
locomotor velocity, 3 cm s1 for the 1/15 scale model,
translates to only 48 cm s1 (1.73 km h1),
less than half the 4 km h1 swimming speed (1.11 m
s1) used in the mathematical model, yet the tank was too
small to allow forward motion at 1/15 scale (7.5 cm s1) for
more than 7 or 8 s. Because intermittent movement of the model for short
durations could affect flow dynamics by introducing acceleration effects, I
present here only data from a stationary model. Still, in no sequences were
particles `pushed' ahead or to the sides of the model by a compressive bow
wave, even with a moving model.
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Water clearly flowed from the posterior mouth openings more rapidly than it entered the larger anterior opening. Water/particle flow is best seen in dorsal view, where it is apparent that some particles pass through the mouth but many are trapped in the `baleen', whose fringes, as noted, could not be made as extensive as in life. [Because the balaenid rostrum is so narrow, and because baleen angles outward (medially) from the rostrum, baleen can easily be seen in dorsal view.] Though the lips were immobile, gape could be altered. When the upper jaw was raised too high, i.e. at a gape angle of greater than about 25°, the rostrum created turbulence and fewer particles were captured in the `baleen'.
Mathematical modeling was also performed using the parameters of the physical model's flow tank testing. Resulting values are displayed in Table 2.
Direct pressure measurement
Both types of transducer yielded similar values for direct measurement of
pressures, though only fixed attachment (not dangling transducers) generated
conclusive results. Although pressures could be recorded at the anterior and
posterior oral locations (on the rostrum just posterior to the subrostral
baleen gap, and at the rear of the mouth above the root of the tongue,
respectively, with transducer tip perpendicular to flow), measurement from the
orolabial sulcus did not yield significant pressure changes, positive or
negative. Pressures recorded from the front of the mouth were only slightly
less than ambient (87±0.29 Pa; mean ±
S.E.M., N=38), but those from the
rear location were significantly lower (588±0.66 Pa; mean
± S.E.M., N=38; both recorded
at flow velocity=3 cm s1). Thus there was a mean pressure
differential, from the anterior to the posterior of the mouth, of 500 Pa or
3.76 mmHg (Fig. 5B).
Although this value is lower than those derived from the mathematical model
(1469 Pa from Bernouilli's equation; 1499 Pa and 1628 Pa
from the HagenPoiseuille equations, 1262 Pa from the
NavierStokes equation), it is in the same order of magnitude, and, as
with the qualitative observations of the physical model, serves to corroborate
the results of the mathematical model.
In the few trials in which the physical model's gape was altered (generating turbulent flow, as described above) recorded pressures dropped markedly. Direct pressure measurement varied slightly yet not significantly (P=0.36) with flow velocity. As the upstream flow velocity increased from 3 cm s1 to 5 cm s1, the pressure differential (front to rear of mouth) increased from 461±57 Pa (mean ± S.E.M., N=12) to 543±109 Pa (mean ± S.E.M., N=12), again supporting the fluid mathematical model. Volume flow rate of the test tank could not be altered sufficiently for conclusive experimentation.
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Discussion |
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The mathematical model suggests an intraoral pressure drop of roughly 1420
Pa (11 mmHg) in a 15 m whale swimming at 4 km h1 and
approximately twice that (2910 Pa) in a 15 m whale swimming at 6 km
h1. Results from the physical model
(Fig. 5B) are complementary to
those of the mathematical model (Fig.
6), both quantitatively (a drop of 500 Pa, from direct
pressure measurement in a stationary model and in a moving one at speed
scaling to 1.7 km h1) and qualitatively (higher exit flow
velocity; `pulling' of particle-laden water in anteriorly with no compressive
bow wave; maintenance of laminar flow). All flow involves pressure changes,
but the correspondence of pressure measurements from the fluid and scale
models suggest that the flow of water through the bowhead whale filtration
system is pipe-like.
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Sensitivity analysis is important in any simulation study. Clearly the two principal variables of this continuous ram filtration system (morphometric dimensions and foraging speed) are sensitive to variance. Results from the fluid mathematical modeling indicate that in all cases as foraging velocity (and hence incurrent flow velocity) increases, the pressure differential is greater (Fig. 6). Also, body size plays a factor. With both formulations of the HagenPoiseuille equation, the intraoral pressure drop was substantially greater the smaller the whale. Because most of the measurements were taken from whales with Lb = 1015 m, and since the 1/15 scale physical model was based on dimensions of a 15 m whale, results for this size are likely to be more accurate. Data for smaller whales are particularly suspect (especially for both iterations of the HagenPoiseuille formula) since, as explained earlier, a very young 5 m whale was not available for necropsy; calculations for Lb = 5 m (and 20 m) are rough extrapolations from other whales (these data are provided in Table 2 merely for comparison). For whales in the 1015 m size range, however, all of the various formulae of the mathematical model yield consistently similar results, again suggesting decreased intraoral pressures on the order of (at least) 13002700 Pa (1020 mmHg). It is important to note once again that the foraging gape and speed values were taken from observation and measurement of feeding whales, just as the necropsy measurements came from real whales.
Both models validate the predicted hydrodynamic flow in relative terms, but the values may not reflect estimates of flow velocity and pressure that can be scaled directly to a living whale. The range of variation in pressure values that might reasonably be generated by realistic variation in morphometrics and swimming velocity in a 1015 m whale likely ranges from 1.3 kPa to 13.3 kPa. This is admittedly not a huge drop in pressure, though it ought to be sufficient to improve filtration (if not greatly) and augment the simple hydraulic effects (balaenid whales do not engulf prey via suction, as does the gray whale, Eschrichtius robustus). It must be emphasized, however, that both aspects of this model of the bowhead filtration system conclusively demonstrate reduced intraoral pressures via the Bernouilli and Venturi effects; it seems clear that the decrease in pressure is real and significant.
Running the fluid mathematical model using conditions of the physical model
served to `ground-truth' the modeling. Although this yielded pressure
differentials higher than those calculated with `real' whale measurements
(Table 2), this is not
surprising since body length is a critical factor, and the model represented a
total Lb of just 1 m. Some near-term bowhead fetuses are
five times this length (Koski et al.,
1993). Plugging the physical model into the mathematical model
yielded results (for most equations) in the same order of magnitude as of the
smallest whales shown in Table
2. The mean intraoral pressure drop, for all equations, for the
physical model `swimming' in the flow tank condition of a scale equal to 1.7
km h1 was 33.2 kPa; for that of a 5 m whale at 4 km
h1, 13.6 kPa or about half as much. Further, when a
purely hypothetical 1 m whale (again, much smaller than the average newborn
bowhead of 4.3 m; Koski et al.,
1993
) is used for the mathematical modeling, the results are
similar to those using values for the 1 m scale model. Relating the two models
helps to put conclusions about large scale, real world pressure changes on
firmer footing. It not only validates the pressure calculations and
assumptions but also provides further qualitative and quantitative information
about continuity effects. However, one must be very careful when assuming that
pressures measured (and calculated) from the 1/15 scale model would be
identical to those of a real whale swimming at higher speed under different
Reynolds conditions. This modeling is limited by the simplicity of its
assumptions, particularly when considering if the models have true predictive
value in absolute terms.
Due to the slick, streamlined nature of the pipe-like oral channel and the steady, relatively slow speed of flow, it is unlikely that turbulence is generated; the models' laminar, frictionless conditions are validated. It is important to consider differences in fluid force scaling from real filtering whales to the physical model head in the flow tank (with smaller size and lower velocities), yielding a one thousand-fold difference in Reynolds number (1.8x103 for the model; 2.5x106 for actual whales at the feeding velocity used in this study; flow velocity in the test tank could not be scaled perfectly to the latter Re). The lower Re value reflects laminar pipe flow. The larger figure, for real whales, reveals flow that could be transitioning to turbulent, and this would have major implications for the equations of the mathematical model that assume laminar flow. Of course, the Re regime would differ in feeding whales depending on swimming speed and gape (and hence dimensions of the oral pipe), though neither factor is expected to vary appreciably. Changes in the baleen filter (particularly fringe density and thus porosity and resistance, R) would also affect flow velocity and thus alter Re. Even though the Re values vary by three orders of magnitude, both are in the realm of inertial dominance, substantiating the presumption of Bernoulli flow parameters.
The pipe-like nature of the bowhead's continuous filtration system presents an opportunity to calculate the mechanical cost of its filter feeding based on pressurevolume work. Most of the work measured in the pressure drop is likely due to the resistance of the baleen filter. Using the pressure differential from the Bernoulli equation calculations, one can back out the resistance in the HagenPoiseuille equation and, after removing pipe length and diameter effects, estimate the resistance added by the baleen. This yields estimates of resistance of R=146.7 N m2 for a whale foraging at 4 km h1 and R=332.6 N m2 for a whale foraging at 6 km h1. These values compare quite favorably to the resistance measured from the 1/15 scale physical model's `baleen' filter, cited earlier, of R=288.14 N m2. Again there is concordance between the two models.
In their study of bowhead baleen contours, Lambertsen et al.
(1989) proposed that the curved
cross-sectional shape of each plate as well the laterally bowed profile of
each baleen rack might accentuate a pressure gradient, resulting in improved
filtering efficiency. The characteristic sluggishness of balaenids is often
ascribed to the giant filter's high resistance to water flow, generating
pressure drag that severely slows feeding whales and prohibits capture of
large or evasive prey (Sanderson and
Wassersug, 1990
). Reduced intraoral pressure could negate the
compressive effect of the forward locomotion powering this system, perhaps
allowing balaenids to swim faster and alleviating or entirely eliminating bow
waves that disperse prey or prompt prey to take evasive action. However,
frictional drag would increase as a square of velocity, adding to the forward
resistance and thus likely keeping swimming speed low. Würsig and Clark
(1993
) suggested that bowheads
also benefit from foraging in tight V-shaped echelons that apparently limit
prey escape. The Bernoulli and Venturi effects may produce anterior suction
(albeit of negligible pressure) for prey capture; the
15003000 Pa
values furnished by the mathematical model for a 15 m whale would certainly
prove sufficient to draw in typical (minute) prey items or at least prevent
their escape. Again, continuity effects might also aid in capture of particles
flowing through the oral cavity
(Rubenstein and Koehl,
1977
).
As Vogel (1994) noted, a
swimming fish with open mouth resembles a Pitot tube. Velocity changes outside
the head (via the Bernouilli effect) create a pressure gradient, with
water entering at the mouth at the point of high pressure and exiting
(posterior to the gills) at lower pressure. This serves to enhance and
facilitate both ram ventilation and ram feeding. Given that balaenid (bowhead
and right) whales, unlike other mysticetes, have continuous ram filtration
with the buccal cavity open at the front and back, as in fishes, the same
phenomenon should apply. Velocity changes outside the head should create a
complementary mechanism to the one in operation internally to augment
filtration further.
Clearly, the balaenid filter feeding mechanism is not as straightforward as
is commonly described. Since baleen is not a rigid material, filter porosity
varies according to such hydrodynamic factors as swimming speed, size and
density of prey, and direction and pressure of water flow
(Sanderson and Wassersug,
1990). Other elements of this continuous filtration system
demonstrate complex mobility. The muscular balaenid tongue is often implicated
in removal of captured prey from baleen, yet underwater footage of right
whales Eubalaena glacialis shows the elevated tongue sweeping
laterally, perhaps to direct water flow into the baleen (Werth,
1990
,
2000
). It is possible that
hydrodynamic effects could be preferentially increased on either side of the
oral cavity. Unfortunately, exceptionally low visibility at high prey
densities precludes filming of this behavior. The large, mobile lip and
mandible (with unfused symphysis) also play critical roles in feeding. Fibers
of the temporalis muscle insert in the lip
(Fig. 4) to allow outward
rotation, establishing the gutter-like channel lateral to the baleen.
Due to the many legal and logistical limitations, studies of large marine mammals require ingenuity and resourcefulness. In the absence of direct experimental evidence, and with only limited, anecdotal observational evidence, modeling provides a convenient tool to investigate cetacean functional morphology. Future use of a larger flow tank and a transparent physical model would allow for more direct observation of interior flow fields. Likewise testing of this model at different locations in the water column, including surface and half-submerged positions (as is common, though far from exclusive, in bowhead feeding) should indicate the influence of gravity, if any, on these hydrodynamic effects.
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List of symbols and abbreviations |
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Acknowledgments |
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References |
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