Publications

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Book Chapter
Kooyman, G, Ponganis PJ.  1990.  Behavior and physiology of diving in emperor and king penguins. Penguin biology. ( Davis L, Darby JT, Eds.).:14., San Diego: Academic Press Abstract
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Ponganis, PJ, Kooyman GL, h. Ridgway S.  2003.  Comparative Diving Physiology. Bennett and Elliott's physiology and medicine of diving. ( Brubakk AO, Neuman TS, Bennett PB, Elliott DH, Eds.).:16., Edinburgh; New York: Saunders Abstract
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Kooyman, GL, Ponganis PJ, Howard RS.  1999.  Diving Animals. The lung at depth. ( Lundgren CEG, Miller JN, Eds.).:587-620., New York: Marcel Dekker Abstract
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Conference Proceedings
Ponganis, PJ, Kooyman GL.  1990.  Diving physiology of penguins. Acta XX Congressus Internationalis Ornithologici, Christchurch, New Zealand, 2-9 December 1990. ( Butler PJ, Jones DR, Eds.).:6., Wellington, N.Z.: New Zealand Ornithological Congress Trust Board Abstract
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Journal Article
Ponganis, PJ, Kooyman GL, Baranov EA, Thorson PH, Stewart BS.  1997.  The aerobic submersion limit of Baikal seals, Phoca sibirica. Canadian Journal of Zoology-Revue Canadienne De Zoologie. 75:1323-1327.   10.1139/z97-756   AbstractWebsite

An aerobic dive limit (ADL), the diving duration beyond which postdive lactate concentration increases above the resting level, has been estimated theoretically for many species. Such calculations have been based on an oxygen store/diving metabolic rate (MR) equation. Until now, an ADL has been determined empirically from measurements of blood lactate concentration only in the Weddell seal, Leptonychotes weddellii. We measured post-submergence plasma lactate concentrations during spontaneous voluntary submersions of three captive adult Baikal seals (Phoca sibirica). Two-phase regression analysis revealed a transition in the lactate concentration - submersion duration relationship after the animal had been diving for 15 min. Data collected in prior studies on oxygen stores and submersion metabolic rates of Baikal seals yielded a calculated aerobic limit of 16 min. As in Weddell seals, the empirically determined aerobic limit was very similar to the theoretical limit. Furthermore, most diving durations recorded during recent studies of free-ranging Baikal seals are under this limit. These data support the concept of an ADL and its estimation by means of an oxygen store/diving MR calculation.

Knower Stockard, T, Heil J, Meir JU, Sato K, Ponganis KV, Ponganis PJ.  2005.  Air sac P-O2 and oxygen depletion during dives of emperor penguins. Journal of Experimental Biology. 208:2973-2980.   10.1242/jeb.01687   AbstractWebsite

In order to determine the rate and magnitude of respiratory O-2 depletion during dives of emperor penguins (Aptenodytes forsteri), air sac O-2 partial pressure (PO2) was recorded in 73 dives of four birds at an isolated dive hole. These results were evaluated with respect to hypoxic tolerance, the aerobic dive limit (ADL; dive duration beyond which there is post-dive lactate accumulation) and previously measured field metabolic rates (FMRs). 55% of dives were greater in duration than the previously measured 5.6-min ADL. P-O2 and depth profiles revealed compression hyperoxia and gradual O-2 depletion during dives. 42% of final P(O2)s during the dives (recorded during the last 15 s of ascent) were < 20 mmHg (< 2.7 kPa). Assuming that the measured air sac P-O2 is representative of the entire respiratory system, this implies remarkable hypoxic tolerance in emperors. In dives of durations greater than the ADL, the calculated end-of-dive air sac O-2 fraction was < 4%. The respiratory O-2 store depletion rate of an entire dive, based on the change in O-2 fraction during a dive and previously measured diving respiratory volume, ranged from I to 5 ml O-2 kg(-1) min(-1) and decreased exponentially with diving duration. The mean value, 2.1 +/- 0.8 ml O-2 kg(-1) min(-1), was (1) 19-42% of previously measured respiratory O-2 depletion rates during forced submersions and simulated dives, (2) approximately one-third of the predicted total body resting metabolic rate and (3) approximately 10% of the measured FMR. These findings are consistent with a low total body metabolic rate during the dive.

Ponganis, PJ, Kreutzer U, Stockard TK, Lin PC, Sailasuta N, Tran TK, Hurd R, Jue T.  2008.  Blood flow and metabolic regulation in seal muscle during apnea. Journal of Experimental Biology. 211:3323-3332.   10.1242/jeb.018887   AbstractWebsite

In order to examine myoglobin (Mb) function and metabolic responses of seal muscle during progressive ischemia and hypoxemia, Mb saturation and high-energy phosphate levels were monitored with NMR spectroscopy during sleep apnea in elephant seals (Mirounga angustirostris). Muscle blood flow (MBF) was measured with laser-Doppler flowmetry (LDF). During six, spontaneous, 8-12 min apneas of an unrestrained juvenile seal, apneic MBF decreased to 46 +/- 10% of the mean eupneic MBF. By the end of apnea, MBF reached 31 +/- 8% of the eupneic value. The t(1/2) for 90% decline in apneic MBF was 1.9 +/- 1.2 min. The initial post-apneic peak in MBF occurred within 0.20 +/- 0.04 min after the start of eupnea. NMR measurements revealed that Mb desaturated rapidly from its eupenic resting level to a lower steady state value within 4 min after the onset of apnea at rates between 1.7 +/- 1.0 and 3.8 +/- 1.5% min(-1), which corresponded to a muscle O(2) depletion rate of 1-2.3 ml O(2)kg(-1) min(-1). High-energy phosphate levels did not change with apnea. During the transition from apnea to eupnea, Mb resaturated to 95% of its resting level within the first minute. Despite the high Mb concentration in seal muscle, experiments detected Mb diffusing with a translational diffusion coefficient of 4.5 x 10(-7) cm(2) s(-1), consistent with the value observed in rat myocardium. Equipoise P(O2) analysis revealed that Mb is the predominant intracellular O(2) transporter in elephant seals during eupnea and apnea.

Meir, JU, Robinson PW, Vilchis LI, Kooyman GL, Costa DP, Ponganis PJ.  2013.  Blood oxygen depletion is independent of dive function in a deep diving vertebrate, the northern elephant seal. Plos One. 8   10.1371/journal.pone.0083248   AbstractWebsite

Although energetics is fundamental to animal ecology, traditional methods of determining metabolic rate are neither direct nor instantaneous. Recently, continuous blood oxygen (O-2) measurements were used to assess energy expenditure in diving elephant seals (Mirounga angustirostris), demonstrating that an exceptional hypoxemic tolerance and exquisite management of blood O-2 stores underlie the extraordinary diving capability of this consummate diver. As the detailed relationship of energy expenditure and dive behavior remains unknown, we integrated behavior, ecology, and physiology to characterize the costs of different types of dives of elephant seals. Elephant seal dive profiles were analyzed and O-2 utilization was classified according to dive type (overall function of dive: transit, foraging, food processing/rest). This is the first account linking behavior at this level with in vivo blood O-2 measurements in an animal freely diving at sea, allowing us to assess patterns of O-2 utilization and energy expenditure between various behaviors and activities in an animal in the wild. In routine dives of elephant seals, the blood O-2 store was significantly depleted to a similar range irrespective of dive function, suggesting that all dive types have equal costs in terms of blood O-2 depletion. Here, we present the first physiological evidence that all dive types have similarly high blood O-2 demands, supporting an energy balance strategy achieved by devoting one major task to a given dive, thereby separating dive functions into distinct dive types. This strategy may optimize O-2 store utilization and recovery, consequently maximizing time underwater and allowing these animals to take full advantage of their underwater resources. This approach may be important to optimizing energy expenditure throughout a dive bout or at-sea foraging trip and is well suited to the lifestyle of an elephant seal, which spends >90% of its time at sea submerged making diving its most "natural" state.

Ponganis, PJ, Kooyman GL, Zornow MH, Castellini MA, Croll DA.  1990.  Cardiac output and stroke volume in swimming harbor seals. Journal of Comparative Physiology B-Biochemical Systemic and Environmental Physiology. 160:473-482.   10.1007/BF00258974   AbstractWebsite

Cardiac output was measured by the thermodilution method in three young harbor seals, at rest and while swimming up to the maximum effort for which they could be trained. Stroke volume was determined by counting heart rate simultaneously with determination of cardiac output. Cardiac outputs varied widely between surface breathing (7.8 ml.kg-1.s-1) and breath-holding while swimming under water (1.8 ml.kg-1.s-1). Stroke volume while at the surface was almost twice the volume while submerged. Surface cardiac output was always near maximal despite work effort, whereas submerged cardiac output gradually increased at higher work efforts. The cardiovascular performance of seals at the maximum MO2 we could induce from them is equivalent to that of the domestic goat.

Ponganis, PJ, Kooyman GL, Zornow MH.  1991.  Cardiac output in swimming California sea lions, Zalophus californianus. Physiological Zoology. 64:1296-1306. AbstractWebsite

Cardiac output was determined by the thermodilution technique in three California sea lions while resting and while swimming. Metabolic rates increased seven-to ninefold above resting rates during maximal exercise. While the sea lions were at rest, stroke volume was also determined by simultaneously counting heart rate during cardiac output determinations. At rest, cardiac output (2.5-3.0 mL kg-1s-1) and stroke volume (2 mL kg-1) were similar to those of harbor seals and terrestrial mammals of similar mass. During exercise, mean cardiac output increased linearly with work load and surface/submerged intervals were short and frequent. The exercise capacity of swimming sea lions appears similar to that of harbor seals, but the exercise response resembles that of terrestrial mammals more than that of harbor seals.

Kooyman, GL, Ponganis PJ.  1997.  The challenges of diving to depth. American Scientist. 85:530-539. AbstractWebsite
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Kooyman, GL, Ponganis PJ.  2014.  Chick production at the largest emperor penguin colony decreases by 50% from 2008-10. Antarctic Science. 26:33-37.   10.1017/s0954102013000515   AbstractWebsite

The emperor penguin colony at Coulman Island is reputedly the largest known. This reputation is based on intermittent ground and aerial surveys performed since 1958. From an aerial survey obtained on 28 October 2010 we discovered that the total number of chicks was 56% of the lowest previous estimate of 2006 and only 41% of the most recent estimate in 2008. All of the counts tallied since 1983 were determined either by ground counts or from aerial film or digital photographs, or estimates from adult counts. We also determined the sea ice conditions in autumn, which is close to the time the adults arrive to breed. We present three hypotheses of what might have happened from 2008-10 to cause the step change in chick production, the small recovery of chick numbers in 2011, and the complete recovery of number of adults from 2010-11. We conclude that local circumstances may have strongly influenced the breeding behaviour of the emperor penguins in 2010 and to a lesser degree in 2011 when many adults elected not to breed.

Ponganis, PJ, van Dam RP, Knower T, Levenson DH, Ponganis KV.  2004.  Deep dives and aortic temperatures of emperor penguins: new directions for bio-logging at the isolated dive hole. Memoirs of National Institute of Polar Research Special Issue. 58:155-161. AbstractWebsite
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Ponganis, PJ, Kreutzer U, Sailasuta N, Knower T, Hurd R, Jue T.  2002.  Detection of myoglobin desaturation in Mirounga angustirostris during apnea. American Journal of Physiology-Regulatory Integrative and Comparative Physiology. 282:R267-R272. AbstractWebsite

H-1 NMR solution-state study of elephant seal (Mirounga angustirostris) myoglobin (Mb) and hemoglobin (Hb) establishes the temperature-dependent chemical shifts of the proximal histidyl NdeltaH signal, which reflects the respective intracellular and vascular PO2 in vivo. Both proteins exist predominantly in one major isoform and do not exhibit any conformational heterogeneity. The Mb and Hb signals are detectable in M. angustirostris tissue in vivo. During eupnea M. angustirostris muscle maintains a well-saturated MbO(2). However, during apnea, the deoxymyoglobin proximal histidyl NdeltaH signal becomes visible, reflecting a declining tissue PO2. The study establishes a firm methodological basis for using NMR to investigate the metabolic responses during sleep apnea of the elephant seal and to secure insights into oxygen regulation in diving mammals.

Ponganis, PJ, Kooyman GL, Castellini MA.  1993.  Determinants of the aerobic dive limit of Weddell seals: analysis of diving metabolic rates, postdive end tidal PO2's, and blood and muscle oxygen stores. Physiological Zoology. 66:732-749. AbstractWebsite

The mean aerobic dive limit (ADL) for Weddell seals was calculated from data collected on diving metabolic rates (VO2) and blood and muscle O2 stores. Mean diving VO2 of adult seals during predominantly exploratory dive patterns was 4.5 mL O2 kg-1 min-1; mean VO2 of a subadult seal engaged in foraging dive bouts was 8.5 mL O2 kg-1 min-1. The adult value was 30% greater than that used in past ADL calculations. Mean plasma volume was 7% body mass (BM); blood volume calculated with the highest hematocrit (Hct) observed (66) was 21% BM. Hemoglobin concentration at such an Hct was 26% by weight. End tidal PO2 (pre- and postdive) justified the use of 95% and 20% arterial O2 saturations in the blood O2 store calculation. Total blood O2 stores were 50% greater than those used in past ADL calculations. Mean myoglobin concentration (5.4% by weight) and more recent anatomical estimates of muscle mass yielded a 35% increase in muscle O2 stores. The mean estimated ADL for a 450-kg seal calculated with these new data was 19.1 min, 2.3 min greater than in past calculations and only 1 min less than the 20-min inflection point of the curve of dive duration versus postdive lactic acid appearance. For the subadult engaged in foraging dives, the mean estimated ADL was about 9 min, again quite similar to past ADL calculations.

Ponganis, PJ, Starke LN, Horning M, Kooyman GL.  1999.  Development of diving capacity in emperor penguins. Journal of Experimental Biology. 202:781-786. AbstractWebsite

To compare the diving capacities of juvenile and adult emperor penguins Aptenodytes forsteri, and to determine the physiological variables underlying the diving ability of juveniles, we monitored diving activity in juvenile penguins fitted with satellite-linked time/depth recorders and examined developmental changes in body mass (M-b), hemoglobin concentration, myoglobin (Mb) content and muscle citrate synthase and lactate dehydrogenase activities, Diving depth, diving duration and time-at-depth histograms were obtained from two fledged juveniles during the first 2.5 months after their departure from the Cape Washingon colony in the Ross Sea, Antarctica. During this period, values of all three diving variables increased progressively. After 8-10 weeks at sea, 24-41% of transmitted maximum diving depths were between 80 and 200 m, Although most dives lasted less than 2 min during the 2 month period, 8-25% of transmitted dives in the last 2 weeks lasted 2-4 min. These values are lower than those previously recorded in adults during foraging trips. Of the physiological variables examined during chick and juvenile development, only M-b and Mb content did not approach adult values, In both near-hedge chicks and juveniles, Mb was 50-60% of adult values and Mb content was 24-31% of adult values. This suggests that the increase in diving capacity of juveniles at sea will be most dependent on changes in these factors.

Eckert, SA, Eckert KL, Ponganis P, Kooyman GL.  1989.  Diving and foraging behavior of leatherback sea turtles (Dermochelys coriacea). Canadian Journal of Zoology-Revue Canadienne De Zoologie. 67:2834-2840.   10.1139/z89-399   AbstractWebsite

Remote time–depth recorders (TDR) were deployed on six gravid leatherbacks nesting on Sandy Point, St. Croix. Dive behavior was monitored continuously for each turtle during internesting intervals ranging from 9 to 11 days. Dive duration averaged 9.9 min/dive (SD = 5.3, n = 5096); mean depth was 61.6 m (SD = 59.1, n = 5096). One turtle dived twice beyond the range of her TDR to depths we estimate >1000 m. Postdive surfacing intervals averaged 4.9 min/dive (SD = 13.1, n = 5090). Differences in mean dive depth, dive duration, and surface intervals among turtles were not attributable to differences in body size (length or mass). Distinct diel periodicity was observed in dive behavior; submergence intervals were longest at dawn, declined throughout the day, and were shortest at dusk. Night dives (19:00–04:59) were shorter, shallower, and more frequent than day dives (05:00–18:59). Dive depth was less variable at night than during the day. The dive pattern suggests nocturnal foraging within the deep scattering layer, a hypothesis that is corroborated by seasonal weight loss data.

Ponganis, PJ, Kooyman GL.  2000.  Diving physiology of birds: a history of studies on polar species. Comparative Biochemistry and Physiology a-Molecular and Integrative Physiology. 126:143-151.   10.1016/s1095-6433(00)00208-7   AbstractWebsite

Our knowledge of avian diving physiology has been based primarily on research with polar species. Since Scholander's 1940 monograph, research has expanded from examination of the 'diving reflex' to studies of free-diving birds, and has included laboratory investigations of oxygen stores, muscle adaptations, pressure effects, and cardiovascular/metabolic responses to swimming exercise. Behavioral and energetic studies at sea have shown that common diving durations of many avian species exceed the calculated aerobic diving limits (ADL). Current physiological research is focused on factors, such as heart rate and temperature, which potentially affect the diving metabolic rate and duration of aerobic diving. (C) 2000 Elsevier Science Inc. All rights reserved.

Kooyman, GL, Ainley DG, Ballard G, Ponganis PJ.  2007.  Effects of giant icebergs on two emperor penguin colonies in the Ross Sea, Antarctica. Antarctic Science. 19:31-38.   10.1017/s0954102007000065   AbstractWebsite

The arrival in January 2001 in the south-west Ross Sea of two giant icebergs, C16 and Bl5A, subsequently had dramatic affects on two emperor penguin colonies. B15A collided with the north-west tongue of the Ross Ice Shelf at Cape Crozier, Ross Island, in the following months and destroyed the penguins' nesting habitat. The colony totally failed in 2001, and years after, with the icebergs still in place, exhibited reduced production that ranged from 0 to 40% of the 1201 chicks produced in 2000. At Beaufort Island, 70 km NW of Crozier, chick production declined to 6% of the 2000 count by 2004. Collisions with the Ross Ice Shelf at Cape Crozier caused incubating adults to be crushed, trapped in ravines, or to abandon the colony and, since 2001, to occupy poorer habitat. The icebergs separated Beaufort Island from the Ross Sea Polynya, formerly an easy route to feeding and wintering areas. This episode has provided a glimpse of events which have probably occurred infrequently since the West Antarctic Ice Sheet began to retreat 12 000 years ago. The results allow assessment of recovery rates for one colony decimated by both adult and chick mortality, and the other colony by adult abandonment and chick mortality.

Jobsis, PD, Ponganis PJ, Kooyman GL.  2001.  Effects of training on forced submersion responses in harbor seals. Journal of Experimental Biology. 204:3877-3885. AbstractWebsite

In several pinniped species, the heart rates observed during unrestrained dives are frequently higher than the severe bradycardias recorded during forced submersions. To examine other physiological components of the classic 'dive response' during such moderate bradycardias, a training protocol was developed to habituate harbor seals (Phoca vitulina) to short forced submersions. Significant changes were observed between physiological measurements made during naive and trained submersions (3-3.5min). Differences were found in measurements of heart rate during submersion (naive 18 +/-4.3 beats min(-1) versus trained 35 +/-3.4 beats min(-1)), muscle blood flow measured using laser-Doppler flowmetry (naive 1.8 +/-0.8 ml min(-1) 100 g(-1) versus trained 5.8 +/-3.9 ml min(-1) 100 g(-1)), change in venous P-O 2 (naive -0.44 +/-1.25 kPa versus trained -1.48 +/-0.76 kPa) and muscle deoxygenation rate (naive -0.67 +/-0.27 mvd s(-1) versus trained -0.51 +/-0.18 mvd s(-1), a relative measure of muscle oxygenation provided by the Vander Niroscope, where mvd are milli-vander units). In contrast to the naive situation, the post-submersion increase in plasma lactate levels was only rarely significant in trained seals. Resting eupneic (while breathing) heart rate and total oxygen consumption rates (measured in two seals) were not significantly different between the naive and trained states. This training protocol revealed that the higher heart rate and greater muscle blood flow in the trained seals were associated with a lower muscle deoxygenation rate, presumably secondary to greater extraction of blood O-2 during trained submersions. Supplementation of muscle oxygenation by blood O-2 delivery during diving would increase the rate of blood O-2 depletion but could prolong the duration of aerobic muscle metabolism during diving. This alteration of the dive response may increase the metabolic efficiency of diving.

Kooyman, GL, Ponganis PJ.  1994.  Emperor penguin oxygen consumption, heart rate and plasma lactate levels during graded swimming exercise. Journal of Experimental Biology. 195:199-209. AbstractWebsite

Oxygen consumption (V-O2), heart rate and blood chemistry were measured in four emperor penguins, Aptenodytes forsteri (Gray), during graded swimming exercise. The maximum V-O2, obtained, 52ml O-2 kg(-1) min(-1), was 7.8 times the measured resting V-O2 of 6.7 ml O-2 kg(-1) min(-1) and 9.1 times the predicted resting V-O2. As the swimming effort rose, a linear increase in surface and submerged heart rates (fH) occurred. The highest average maximum surface and submersion heart rates of any bird were 213 and 210 beats min(-1), respectively. No increase in plasma lactate concentrations occurred until V-O2 was greater than 25 ml O-2 kg(-1) min(-1). At the highest V-O2 values measured, plasma lactate concentration reached 9.4 mmol l(-1). In comparison with other animals of approximately the same mass, the aerobic capacity of the emperor penguin is less than those of the emu and dog but about the same as those of the seal, sea lion and domestic goat. For aquatic animals, a low aerobic capacity seems to be consistent with the needs of parsimonious oxygen utilization while breath-holding.

Nagy, KA, Kooyman GL, Ponganis PJ.  2001.  Energetic cost of foraging in free-diving emperor penguins. Physiological and Biochemical Zoology. 74:541-547.   10.1086/322165   AbstractWebsite

Hypothesizing that emperor penguins (Aptenodytes forsteri) would have higher daily energy expenditures when foraging for their food than when being hand-fed and that the increased expenditure could represent their foraging cost, we measured field metabolic rates (FMR; using doubly labeled water) over 4-d periods when 10 penguins either foraged under sea ice or were not allowed to dive but were fed fish by hand. Surprisingly, penguins did not have higher rates of energy expenditure when they dove and captured their own food than when they did not forage but were given food. Analysis of time-activity and energy budgets indicated that FMR was about 1.7 x BMR (basal metabolic rate) during the 12 h d(-1) that penguins were lying on sea ice. During the remaining 12 h d(-1), which we termed their "foraging period" of the day, the birds were alert and active (standing, preening, walking, and either free diving or being hand-fed), and their FMR was about 4.1 x BMR. This is the lowest cost of foraging estimated to date among the eight penguin species studied. The calculated aerobic diving limit (ADL(C)), determined with the foraging period metabolic rate of 4.1 x BMR and known O-2 stores, was only 2.6 min, which is far less than the 6-min ADL previously measured with postdive lactate analyses in emperors diving under similar conditions. This indicates that calculating ADL(C) from an at-sea or foraging-period metabolic rate in penguins is not appropriate. The relatively low foraging cost for emperor penguins contributes to their relatively low total daily FMR (2.9 x BMR). The allometric relationship for FMR in eight penguin species, including the smallest and largest living representatives, is kJ d(-1) = 1,185 kg(0.705).

Ancel, A, Starke LN, Ponganis PJ, Van Dam R, Kooyman GL.  2000.  Energetics of surface swimming in Brandt's cormorants (Phalacrocorax penicillatus Brandt). Journal of Experimental Biology. 203:3727-3731. AbstractWebsite

The energy requirements of Brandt's cormorants (Phalacrocorax penicillatus) during surface swimming were measured in birds swimming under a metabolic chamber in a water flume. From the oxygen consumption recordings, we extrapolated the metabolic rate and cost of transport at water speeds ranging from 0 to 1.3 ms(-1). In still water, the birds' mean mass-specific rate of oxygen consumption ((V)over dot(O2),) while floating at the surface was 20.2ml O-2 min(-1) kg(-1), 2.1 times the predicted resting metabolic rate. During steady-state voluntary swimming against a how, their Po, increased with water speed, reaching 74 mi O-2 min(-1) kg(-1) at 1.3 ms(-1), which corresponded to an increase in metabolic rate from 11 to 25 W kg(-1). The cost of transport decreased,vith swimming velocity, approaching a minimum of 19 J kg(-1) m(-1) for a swimming speed of 1.3 m s(-1) Surface swimming in the cormorant costs approximately 18% less than sub-surface swimming. This confirms similar findings in tufted ducks (Aythya fuligula) and supports the hypothesis that increased energy requirements are necessary in these bird diving to overcome buoyancy and heat submergence.

Barber-Meyer, SM, Kooyman GL, Ponganis PJ.  2007.  Estimating the relative abundance of emperor penguins at inaccessible colonies using satellite imagery. Polar Biology. 30:1565-1570.   10.1007/s00300-007-0317-8   AbstractWebsite

Emperor penguin (Aptenodytes forsteri) populations are useful environmental indicators due to the bird's extreme reliance on sea ice. We used remote sensing technology to estimate relative adult bird abundance at two inaccessible emperor penguin colonies in the Ross Sea, Antarctica. We performed supervised classification of 12 panchromatic satellite images of the seven known Ross Sea colonies. We used regression to predict adult bird counts at the inaccessible colonies by relating the number of pixels classified as "penguin" in the satellite images of the accessible colonies to corresponding known adult bird counts from aerial photographs or ground counts. While our analysis was hampered by excessive guano and shadows, we used satellite imagery to differentiate between relatively small (< 3,000 adult birds) and larger colonies (> 5,000 adult birds). Remote sensing technology is logistically less intense and less costly than aerial or ground censuses when the objective is to document penguin presence and/or large emperor penguin population changes (e.g., catastrophic changes). Improvements expected soon in the resolution of the satellite images should allow for more accurate abundance estimates.

Blight, LK, Ainley DG, Ackley SF, Ballard G, Ballerini T, Brownell RL, Cheng CHC, Chiantore M, Costa D, Coulter MC, Dayton P, Devries AL, Dunbar R, Earle S, Eastman JT, Emslie SD, Evans CW, Garrott RA, Kim S, Kooyman G, Lescroel A, Lizotte M, Massaro M, Olmastroni S, Ponganis PJ, Russell J, Siniff DB, Smith WO, Stewart BS, Stirling I, Willis J, Wilson P, Woehler EJ.  2010.  Fishing for data in the Ross Sea. Science. 330:1316-1316.   10.1126/science.330.6009.1316   AbstractWebsite
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