The Answer Lies In A Bone-shaking Triangle

Many a love-besotted soul has declared they would move the world for their true love, but how many actually accomplish that task in their quest to unite with a lover?

Poets and romantics may argue the point, but research has shown that elephants issuing calls, including those of love—more precisely, females in estrus—produce not only audible sounds, but also low-frequency seismic vibrations that can travel through the near-surface soils for distances up to several kilometers.

And though we humans may claim to feel our lover’s call in our heart, soul or other organs of either physical or philosophical origin, most of us need said love call to caress the hair cells of our inner ears for it to register in what is arguably our most important love/sex organ—our brain.

Elephants, however, have two highly developed additional sensory systems at their disposal, both of which can be used for detecting the potential mate’s seismic signals (humans have both, too, just not tuned to using vibrations as communication). One system is bone conduction, in which the vibrations travel from the toe tips into the foot bones, then up the leg and into the middle ear. The other, somatosensory reception, involves vibration-sensitive cells in the bottom of the foot that send signals to the brain via nerves.

Caitlin O’Connell-Rodwell, an ecologist and consulting assistant professor in otolaryngology at Stanford University School of Medicine, has been studying elephant communication for more than 15 years. During that time she’s puzzled over which seismic sensing system elephants use most often in locating the source of a call. In her most recent field season last summer, she finally got an answer.

“They are placing themselves in a way that best suits bone conduction, rather than somato-sensory reception,” she said.

O’Connell-Rodwell came to her conclusion by conducting a study of how male elephants respond to estrus calls from females. She played recorded calls through a speaker coupled with the ground and concealed in a pile of brush near a watering hole in Etosha National Park in Namibia. The speaker emitted both an acoustic and seismic signal.

“The bulls would come in and then we would test them as they headed out of the water hole in different directions. They would always place themselves perpendicular to the direction the sound had traveled,” she said.

That orientation puts each of the elephant’s ears at a different distance from the sound source and also creates the maximum possible difference in the distance between each of the elephant’s ears and the source. That enhances their ability to distinguish the point of origin. This position was assumed by the elephants whether the signal was only seismic or both acoustic and seismic, suggesting that bone-conducted detection was the preferable method for detecting seismic frequencies. If the elephants preferred somatosensory reception, they would more likely align their front and back feet to create the greatest difference in distance from the source to each pair of feet. But perhaps that’s where the trunk comes in.

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