Collaborative Research: Geomagnetic Navigation by Weddell Seals Beneath Antarctic Ice

合作研究：威德尔海豹在南极冰层下进行地磁导航

• 批准号: 1341469
• 负责人: Randall Davis
• 金额: $ 39.44万
• 依托单位: Texas A&M University
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-07-01 至 2020-09-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1341469&HistoricalAwards=false
• 关键词: Collaborative; Research; Geomagnetic; Navigation; Weddell

The remarkable ability of many animals to navigate accurately over long distances has defied scientific explanation despite decades of research on species such as homing pigeons. Evidence that marine mammals use the Earth's magnetic field for navigation is less clear but numerous reports infer this sensory capability in a variety of marine mammals. Mistakes in this mechanism may be involved in mass strandings of whales and dolphins and a better understanding of marine mammal navigation ultimately may be useful in preventing or forecasting these events. Weddell seals precisely locate breathing holes in Antarctic sea ice after traveling hundreds of meters in darkness and a navigation mistake can result in death. In this project, the investigators will test a novel idea about marine mammal sub-ice navigation and orientation using geomagnetic fields by employing a custom-designed video and data recorder capable of monitoring fine-scale animal behaviors and movements when diving. The project will also further the NSF goals of making scientific discoveries available to the general public and of training new generations of scientists. The general public will be involved via web sites, a lecture series targeting underrepresented groups, and development of nationally disseminated K-12 teaching materials. A number of graduate and undergraduate students will be trained in the techniques of scientific discovery over the course of the project.With limited oxygen stores during under-ice diving, Weddell seals are under strong selective pressure to navigate accurately and efficiently to locate breathing holes. The investigators hypothesize that geomagnetic navigation is both necessary and sufficient for Weddell seals to return to the vicinity of breathing holes. This project will be the first to rigorously field test geomagnetic navigation in a marine mammal as well as the first to measure the energetic cost of geomagnetic navigational behavior and evaluate how body oxygen stores and breath-hold duration influence spatial orientation and navigational strategies in a diving mammal. The investigators will measure changes in the behavioral and energetic responses of individual seals to different geomagnetic field properties and test those responses against precise predictions. By conducting tests during periods of high light intensity/long day length and low light intensity/reduced day length while simultaneously documenting sound sources and water currents, the experimental design provides a powerful technique for identifying a geomagnetic response as other sensory modalities are manipulated. These costs will be compared to those of other vertebrates to assess the evolutionary drivers for geomagnetic navigation. Demonstration of geomagnetic navigation in seals would also provide new insights into fine scale activities of other diving animals and the mechanisms that enable long distance migrations. Thus, the results have the potential to transform our understanding of navigation in all diving animals.

尽管对信鸽等物种进行了数十年的研究，但许多动物长距离精确导航的卓越能力仍无法得到科学解释。海洋哺乳动物利用地球磁场进行导航的证据尚不清楚，但大量报告推断多种海洋哺乳动物具有这种感觉能力。这种机制中的错误可能与鲸鱼和海豚的大规模搁浅有关，更好地了解海洋哺乳动物的航行最终可能有助于预防或预测这些事件。威德尔海豹在黑暗中航行数百米后，精确定位南极海冰上的呼吸孔，导航错误可能导致死亡。在这个项目中，研究人员将通过使用定制设计的视频和数据记录器来测试关于利用地磁场进行海洋哺乳动物冰下导航和定向的新颖想法，该视频和数据记录器能够在潜水时监测精细动物的行为和运动。该项目还将进一步推进国家科学基金会的目标，即向公众提供科学发现和培训新一代科学家。公众将通过网站、针对代表性不足群体的系列讲座以及编写全国传播的 K-12 教材来参与其中。在该项目过程中，一些研究生和本科生将接受科学发现技术方面的培训。在冰下潜水期间，由于氧气储存有限，威德尔海豹在强大的选择压力下准确有效地导航以找到呼吸孔。研究人员假设，地磁导航对于威德尔海豹返回呼吸孔附近既必要又充分。该项目将是第一个对海洋哺乳动物的地磁导航进行严格现场测试的项目，也是第一个测量地磁导航行为的能量成本并评估身体氧气储存和屏气持续时间如何影响潜水中的空间定向和导航策略的项目。哺乳动物。研究人员将测量个体海豹对不同地磁场特性的行为和能量反应的变化，并根据精确的预测测试这些反应。通过在高光强/长日长和低光强/短日长期间进行测试，同时记录声源和水流，实验设计提供了一种强大的技术，可以在操纵其他感官模式时识别地磁响应。这些成本将与其他脊椎动物的成本进行比较，以评估地磁导航的进化驱动因素。海豹地磁导航的演示也将为了解其他潜水动物的精细活动以及实现长距离迁徙的机制提供新的见解。因此，这些结果有可能改变我们对所有潜水动物导航的理解。