Tracking pigeons in a magnetic anomaly and in magnetically “quiet” terrain

Schiffner, Ingo; Fuhrmann, Patrick; Wiltschko, Roswitha

doi:10.1007/s00114-011-0802-3

Cited by 18 publications

(13 citation statements)

References 22 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A magnetic map based on the combination of geomagnetic intensity and inclination may affect orientation [3], ecophysiology [6,7] and activity [8,9] in bird migrants. Furthermore, local geomagnetic anomalies caused by the characteristics of the Earth's crust can disrupt birds' navigation ability [10,11]. Effects of temporal variability caused by solar activity on the geomagnetic field have already received some attention in different organisms (see references in [2]), but less is known about the effects on birds [12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Magnetic storms disrupt nocturnal migratory activity in songbirds

2019

View full text Add to dashboard Cite

Birds possess a magnetic sense and rely on the Earth's magnetic field for orientation during migration. However, the geomagnetic field can be altered by solar activity at relative unpredictable intervals. How birds cope with the temporal geomagnetic variations caused by solar storms during migration is still unclear. We addressed this question by reproducing the effect of a solar storm on the geomagnetic field and monitoring the activity of three songbird species during autumn migration. We found that only the European robin reduced nocturnal migratory restlessness in response to simulated solar storms. At the same time, robins increased activity during early morning. We suggest that robins reduced activity at night when the perception of magnetic information would be strongly disrupted by temporal variations of the magnetic field, to extend their migration during daytime when several visual cues become available for orientation. The other two species, chiffchaff and dunnock, showing low or no nocturnal migratory activity, did not respond to the solar storm by changing activity.

show abstract

Section: Introductionmentioning

confidence: 99%

Magnetic storms disrupt nocturnal migratory activity in songbirds

2019

View full text Add to dashboard Cite

show abstract

“…Nevertheless, in the open sea depth maps often look very different from geomagnetic anomaly maps of the same area. The geomagnetic anomalies can give additional (mis)information for orientation for whales (Klinowska 1985(Klinowska , 1988Walker et al 1992) and other animals (Alerstam 1987;Lohmann et al 2007;Wiltschko et al 2009;Schiffner et al 2011;Brothers & Lohmann 2015). Failure of whales to account for disruptions in the magnetic field, such as those triggered by random and abrupt Solar storms, may thus lead to temporary navigational errors and disorientation (Vanselow & Ricklefs 2005;Vanselow et al 2009;Ferrari 2017).…”

Section: Introductionmentioning

confidence: 99%

Solar storms may trigger sperm whale strandings: explanation approaches for multiple strandings in the North Sea in 2016

Vanselow

Jacobsen

Hall

et al. 2017

International Journal of Astrobiology

View full text Add to dashboard Cite

show abstract

“…One possibility is that anomalies interfere with the normal functioning of magnetic compasses or maps and thus lead to disruptions in orientation and navigation. Consistent with this hypothesis, homing pigeons and migratory birds released at magnetic anomalies show signs of impaired orientation under some conditions (Walcott, 1978(Walcott, , 1992Wiltschko et al, 2009Wiltschko et al, , 2010Schiffner et al, 2011). Alternatively or additionally, such anomalies might be exploited by animals as landmarks (Walker et al, 2002) or otherwise incorporated into navigational strategies.…”

Section: Introductionmentioning

confidence: 89%

Size-dependent avoidance of a strong magnetic anomaly in Caribbean spiny lobsters

Ernst

Lohmann

2018

Journal of Experimental Biology

View full text Add to dashboard Cite

On a global scale, the geomagnetic field varies predictably across the Earth's surface, providing animals that migrate long distances with a reliable source of directional and positional information that can be used to guide their movements. In some locations, however, magnetic minerals in the Earth's crust generate an additional field that enhances or diminishes the overall field, resulting in unusually steep gradients of field intensity within a limited area. How animals respond to such magnetic anomalies is unclear. The Caribbean spiny lobster, , is a benthic marine invertebrate that possesses a magnetic sense and is likely to encounter magnetic anomalies during migratory movements and homing. As a first step toward investigating whether such anomalies affect the behavior of lobsters, a two-choice preference experiment was conducted in which lobsters were allowed to select one of two artificial dens, one beneath a neodymium magnet and the other beneath a non-magnetic weight of similar size and mass (control). Significantly more lobsters selected the control den, demonstrating avoidance of the magnetic anomaly. In addition, lobster size was found to be a significant predictor of den choice: lobsters that selected the anomaly den were significantly smaller as a group than those that chose the control den. Taken together, these findings provide additional evidence for magnetoreception in spiny lobsters, raise the possibility of an ontogenetic shift in how lobsters respond to magnetic fields, and suggest that magnetic anomalies might influence lobster movement in the natural environment.

show abstract

Tracking pigeons in a magnetic anomaly and in magnetically “quiet” terrain

Cited by 18 publications

References 22 publications

Magnetic storms disrupt nocturnal migratory activity in songbirds

Magnetic storms disrupt nocturnal migratory activity in songbirds

Solar storms may trigger sperm whale strandings: explanation approaches for multiple strandings in the North Sea in 2016

Size-dependent avoidance of a strong magnetic anomaly in Caribbean spiny lobsters

Contact Info

Product

Resources

About