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Are elephant whiskers key to their sense of touch?

EarthSky’s Cristina Ortiz explains fascinating new research into elephant whiskers.

Elephant whiskers show nature’s design for touch

Scientists have made a discovery that might change how we understand animal touch. The research team, led by the Max Planck Institute for Intelligent Systems, said on February 12, 2026, that the secret behind the elephant’s extraordinary tactile abilities lies in the material structure of its trunk whiskers.

They found that these specialized hairs allow elephants to sense precise points of contact. This happens despite an elephant’s thick skin and relatively poor eyesight.

The study, published in the peer-reviewed journal Science on February 12, 2026, shows that each whisker has a stiff base that gradually transitions into a soft, rubber-like tip. This change in stiffness along its length lets elephants feel precise contact with objects. As a result, elephants can manipulate delicate objects with astonishing precision. For example, they can grasp something as fragile as a tortilla chip without breaking it, or pick up a peanut with remarkable control.

How material intelligence enhances elephant whiskers

At first, the researchers expected elephant whiskers to resemble those of rodents, which stay uniformly stiff from base to tip. However, detailed imaging and mechanical testing revealed a different structure.

The team used advanced microscopy and nanoindentation (a test where a small probe presses on the whisker to measure stiffness). This allowed the team to examine the whiskers down to the nanometer scale (a billionth of a meter). They discovered the base behaves like rigid plastic, while the tip acts like resilient rubber that bends without breaking or losing its shape.

This gradual shift in stiffness creates what engineers call embodied intelligence. Instead of relying solely on brain signals, the whisker’s material properties themselves encode information about where contact occurs. In other words, the whisker’s structure helps the animal determine how close its trunk is to an object and how it should respond. Co-lead author Andrew K. Schulz expressed his excitement about the finding. He said:

It’s pretty amazing! The stiffness gradient provides a map to allow elephants to detect where contact occurs along each whisker.

Elephant’s trunk touching the ground, visible whiskers fanning out as it surrounds something. — Note the elephant whiskers on the top edge of the trunk. The whiskers are smart sensors that allow elephants to feel their surroundings and grab objects with precision. Image via MPI-IS / A. Posada and Heidelberg Zoo (used with permission).

The architecture of the whiskers

In addition, micro-CT scans (a type of 3D X-ray imaging) showed that elephant whiskers have a flattened, blade-like shape with a hollow base and internal channels. This porous architecture reduces weight and makes the whiskers more durable. Because these hairs never grow back and elephants eat large amounts of food every day, durability is essential. The structure prevents breakage while still allowing sensitive touch.

Gray circle with many wholes inside it. — Microscopic view of an elephant whisker in cross-section. Image via MPI-IS/ D. Philip & H. David (used with permission).

A 3D-printed breakthrough moment

Although the team had discovered the stiffness gradient, they initially struggled to understand how it affected the sense of touch. To explore this in a tangible way, Schulz and his colleagues created a scaled-up 3D-printed whisker. The model had a dark, stiff base and a transparent, soft tip, mimicking the natural whisker.

The turning point came unexpectedly. Co-lead author Katherine J. Kuchenbecker, from the Haptic Intelligence Department at MPI-IS, carried the model through the institute’s hallways. She tapped it against railings and columns, immediately noticing that each section felt different. She explained:

I noticed that tapping the railing with different parts of the whisker wand felt distinct – soft and gentle at the tip, and sharp and strong at the base. I didn’t need to look to know where the contact was happening; I could just feel it.

This simple experiment clarified the concept. The stiffness gradient produces different signals depending on where contact occurs. Computational simulations confirmed this effect. They show the transition from stiff to soft helps elephants detect exactly where something touches the whisker, allowing careful and precise manipulation of objects.

Cats share the elephant whisker secret

Interestingly, elephants are not the only animals with this design. Cats also have whiskers with the same type of stiffness gradient. This similarity suggests that evolution favors this structure in animals that rely heavily on touch for exploring their environment.

Notably, not all elephant hairs follow this pattern. When the researchers compared the Asian elephant’s trunk whiskers to its body hair, they found that body hairs remain stiff from base to tip. This contrast highlights how specially adapted the trunk whiskers are for fine touch rather than general protection. Schulz reflected on the finding:

The hairs on the head, body and tail of Asian elephants are stiff from base to tip, which is what we were expecting when we found the surprising stiffness gradient of elephant trunk whiskers.

A smiling woman and man holding the whisker wand. There is an elephant behind them. — Elephants have stiff body hairs, but trunk whiskers bend and flex, turning touch into a finely tuned sense. Image via MPI-IS (used with permission).

From whiskers to robotics

This discovery could inspire a new generation of robots and sensors. By embedding “smart” features directly into materials, engineers could build devices that sense their environment more accurately, without needing complex computer systems. Schulz highlighted this potential:

Bio-inspired sensors that have an artificial elephant-like stiffness gradient could give precise information with little computational cost purely by intelligent material design.

Dr. Lena V. Kaufmann, a co-author of the study and a neuroscience expert at the Humboldt University of Berlin, explained the bigger picture:

Our findings contribute to our understanding of the tactile perception of these fascinating animals and open up exciting opportunities to further study the relation of whisker material properties and neuronal computation.

The collaboration also included materials scientists from the University of Stuttgart, showing how teamwork across disciplines drives innovation. Reflecting on the project, Kuchenbecker praised the collective effort:

Andrew pulled together an amazing team of engineers, materials scientists, and neuroscientists from five different research groups and led us on an exhilarating three-year-long journey to discover the secrets behind the powerful elephant’s gentle sense of touch.

Two men and 2 women standing behind many computers that show images from the study. — This study was the collaboration of engineers, neuroscientists and materials scientists. They uncovered the sensing of elephant whisker, paving the way for a new generation of robots and materials that can sense and respond like living systems. Image via MPI-IS (used with permission).

Bottom line: Elephant whiskers reveal how giants with thick skin and poor eyesight can sense touch with astonishing delicacy, precision and subtle awareness.

Source: Functional gradients facilitate tactile sensing in elephant whiskers

Via Max Planck Society

The post Are elephant whiskers key to their sense of touch? first appeared on EarthSky.

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EarthSky’s Cristina Ortiz explains fascinating new research into elephant whiskers.

Elephant whiskers show nature’s design for touch

They found that these specialized hairs allow elephants to sense precise points of contact. This happens despite an elephant’s thick skin and relatively poor eyesight.