Emperor penguins leap from the water onto the sea ice. Their ability to reach above-water height depends critically on initial vertical speed of their leaping, assuming that the kinetic energy is converted to gravitational potential energy. We deliberately changed the above-water heights of ice hole exits, in order to examine whether penguins adjusted swim speed in accordance with the above-water height of the ice. Penguins were maintained in a corral on the fast ice in Antarctica, and voluntarily dived through two artificial ice holes. Data loggers were deployed on the penguins to monitor under water behavior. Nine instrumented penguins performed 386 leaps from the holes during experiments. The maximum swim speeds within 1 s before the exits through the holes correlated significantly with the above-water height of the holes. Penguins adopted higher speed to exit through the higher holes than through the lower holes. Speeds of some failed exits were lower than the theoretical minimum values to reach a given height. Penguins failed to exit onto the sea ice in a total of 37 of the trials. There was no preference to use lower holes after they failed to exit through the higher holes. Rather, swim speed was increased for subsequent attempts after failed leaps. These data demonstrated that penguins apparently recognized the above-water height of holes and adopted speeds greater than the minimal vertical speeds to reach the exit height. It is likely, especially in the case of higher holes (>40 cm), that they chose minimum speeds to exit through the holes to avoid excess energy for swimming before leaping. However, some exceptionally high speeds were recorded when they directly exited onto the ice from lower depths. In those cases, birds could increase swim speed without strokes for the final seconds before exit and they only increased the steepness of their body angles as they surfaced, which indicates that the speed required for leaps by emperor penguins were aided by buoyancy, and that penguins can sometimes exit through the ice holes without any stroking effort before leaping.
Download full-text PDF |
Source |
|---|---|
| http://dx.doi.org/10.1242/jeb.01665 | DOI Listing |
Publication Analysis
Top Keywords
Similar Publications
Protein Stability Depends Critically on the Surface Hydrogen-Bonding Network: A Case Study of Bid Protein.
J Phys Chem B
August 2021
Department of Chemistry, National Tsing Hua University, Hsinchu 30013, Taiwan.
Understanding how proteins retain structural stability is not only of fundamental importance in biophysics but also critical to industrial production of antibodies and vaccines. Protein stability is known to depend mainly on two effects: internal hydrophobicity and H-bonding between the protein surface and solvent. A challenging task is to identify their individual contributions to a protein.
View Article and Find Full Text PDFDeployment platforms such as ships, towers or buoys may affect the accuracy of nearby radiometric measurements. Aiming at expanding the know-how on platform perturbations in above-water radiometric measurements, this study investigated the spectral impact of the Acqua Alta Oceanographic Tower (AAOT) on the remote-sensing reflectance RRS as a function of the distance d between the tower and the sensor footprint at the sea surface. This was accomplished by exploiting measurements performed with radiometers operated on deployment rigs extending beyond the AAOT superstructure with sensor viewing angle θ = 40° and relative azimuth ϕ = 90° between sensor and sun.
View Article and Find Full Text PDFFunctional trait evolution in Sphagnum peat mosses and its relationship to niche construction.
New Phytol
July 2019
Department of Biology, Duke University, Campus Box 90338, Durham, NC, 27708, USA.
Species in the genus Sphagnum create, maintain, and dominate boreal peatlands through 'extended phenotypes' that allow these organisms to engineer peatland ecosystems and thereby impact global biogeochemical cycles. One such phenotype is the production of peat, or incompletely decomposed biomass, that accumulates when rates of growth exceed decomposition. Interspecific variation in peat production is thought to be responsible for the establishment and maintenance of ecological gradients such as the microtopographic hummock-hollow gradient, along which sympatric species sort within communities.
View Article and Find Full Text PDFModelling the concentration of chloroform in the air of a Norwegian swimming pool facility-A repeated measures study.
Sci Total Environ
May 2019
Norwegian University of Science and Technology (NTNU), Trondheim, Norway; Department of Industrial Economics and Technology Management, Trondheim, Norway.
Certain volatile disinfection by-products (DBPs) off-gassing from pool water can cause eye and skin irritations, respiratory problems, and even cancer. No guidelines or recommendations concerning DBPs in the air exist in Norway. Traditionally, ventilation strategies in indoor swimming pools are based on reducing condensation on the windows rather than ensuring proper air quality in the users' breathing zone.
View Article and Find Full Text PDFMechanical Harvesting Effectively Controls Young spp. Invasion and Unmanned Aerial Vehicle Data Enhances Post-treatment Monitoring.
Front Plant Sci
April 2017
Inland Fish and Wildlife Department, Sault Ste. Marie Tribe of Chippewa IndiansSault Ste. Marie, MI, USA.
The ecological impacts of invasive plants increase dramatically with time since invasion. Targeting young populations for treatment is therefore an economically and ecologically effective management approach, especially when linked to post-treatment monitoring to evaluate the efficacy of management. However, collecting detailed field-based post-treatment data is prohibitively expensive, typically resulting in inadequate documentation of the ecological effects of invasive plant management.
View Article and Find Full Text PDFWant AI Summaries of new PubMed Abstracts delivered to your In-box?
Enter search terms and have AI summaries delivered each week - change queries or unsubscribe any time!