Sunday, February 15, 2026

 

Elephant trunk whiskers exhibit material intelligence



Scientists discover the secret behind the elephant’s sense of touch




Max Planck Institute for Intelligent Systems

Zookeeper feeling elephant whiskers 

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Photograph of a zookeeper feeling the unusual whiskers that cover an Asian elephant trunk.

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Credit: MPI-IS/A. Posada and Heidelberg Zoo





Stuttgart – A new study from an interdisciplinary German research collaboration, led by the Haptic Intelligence Department at the Max Planck Institute for Intelligent Systems (MPI-IS), reveals the secret to the gentle dexterity of the elephant trunk. The 1000 whiskers that cover the elephant trunk have unusual material properties that highlight where contact happens along each whisker, giving elephants an amazing sense of touch that compensates for their thick skin and poor eyesight.

Recently published in Science with the title “Functional gradients facilitate tactile sensing in elephant whiskers”, this research found that the whiskers of elephants and domestic cats have stiff bases that transition to soft rubber-like tips, different from the uniformly stiff whiskers of rats and mice. Known as a functional gradient, this stiff-to-soft transition allows elephants and cats to brush past objects with ease, helps prevent whisker breakage, and provides unique contact encoding along the whisker’s length. The researchers think this unusual stiffness gradient helps elephants know precisely where contact occurs along each of their 1000 trunk whiskers so they can perform feats like picking up a tortilla chip without breaking it or precisely grabbing a peanut. The research team is looking to invent new robotic sensing technologies inspired by the functional gradients they discovered in elephant and cat whiskers. A video (see link near the bottom of the page) summarizes the motivation for this project and its main findings.

The research was led by a postdoctoral researcher, Dr. Andrew K. Schulz, and Prof. Katherine J. Kuchenbecker from the Haptic Intelligence Department at MPI-IS. They worked with neuroscientists from the Humboldt University of Berlin and materials scientists from the University of Stuttgart. Schulz, the study’s lead author and an Alexander von Humboldt postdoctoral fellow, discussed the start of the project, “I came to Germany as an elephant biomechanics expert who wanted to learn about robotics and sensing. My mentor, Prof. Kuchenbecker, is an expert on haptics and tactile robotics, so a natural bridge was for us to work together on touch sensing through the lens of elephant whiskers.” Schulz and his colleagues used an array of biological, materials science, and engineering techniques to image and characterize 5-cm-long whiskers from elephants and cats down to the length scale of one nanometer, which is 1 billionth of a meter.

The interdisciplinary team examined elephant trunk whiskers to understand how they are shaped (geometry), how porous they are (porosity), and how soft they are (material stiffness). They initially expected elephant whiskers to be similar to the tapered whiskers of mice and rats, which have a circular cross-section, are solid throughout, and have approximately uniform stiffness. Micro-CT allowed the researchers to measure the 3D shape of several whiskers and showed that elephant whiskers are thick and blade-like, with a flattened cross-section, a hollow base, and several long internal channels that resemble the structure of sheep horns and horse hooves. This porous architecture reduces the whisker’s mass and provides impact resistance, allowing elephants to eat hundreds of kilograms of food every day without worrying about damage to their whiskers, which never grow back.

Nanoindentation of both elephant and cat whiskers was performed with a diamond cube indenter the size of a single cell that cyclically pushed into the whisker walls. Indentation performed at the base and the tip of the elephant and cat whiskers showed a transition from a stiff, plastic-like base to a soft, rubber-like tip that could not be permanently indented, a property known as resilience. The team also compared these whiskers to elephant body hair. Schulz said, “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.” While exciting, this discovery initially stumped the team as they were not sure how changing stiffness along a whisker would affect touch sensing.

To try to figure out why, Schulz worked with colleagues at MPI-IS to 3D print a scaled-up whisker with a stiff, dark base and a soft, transparent tip. Having this physical “whisker wand” prototype helped the researchers develop their intuition for what an elephant trunk feels through its whiskers. Schulz left the wand with his mentor after a meeting, and a few days later…Eureka! Kuchenbecker carried the wand in her hand as she walked through the halls of the Institute, gently hitting the columns and railings. She recounted, “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.” 

To test their hypothesis from the 3D-printed whisker wand, the researchers developed a computational modeling toolkit to assess how the unique geometry, porosity, and stiffness gradients they had measured affect how a whisker responds to contact. The simulations showed that the transition from a stiff base to a soft tip does indeed make it easier to feel where something is touching along the whisker, allowing the elephant to react appropriately and carefully manipulate even delicate objects, such as tortilla chips. Schulz said, “It's pretty amazing! The stiffness gradient provides a map to allow elephants to detect where contact occurs along each whisker. This property helps them know how close or how far their trunk is from an object…all baked into the geometry, porosity, and stiffness of the whisker. Engineers call this natural phenomenon embodied intelligence.” Excitingly, domestic cat whiskers show the same kind of stiffness gradient.

This discovery excites Schulz and Kuchenbecker, who are working to apply these insights from nature to applications in robotics and intelligent systems. “Bio-inspired sensors that have an artificial elephant-like stiffness gradient could give precise information with little computational cost purely by intelligent material design,” Schulz said. Dr. Lena V. Kaufmann, a co-author of the study and a neuroscience expert at the Humboldt University of Berlin, is excited about the connections to neuroscience: “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.” Kuchenbecker reflects back on the entire project, “I’m so proud of what we were able to figure out by working together across disciplines. 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.”

 

Reference:

“Functional gradients facilitate tactile sensing in elephant whiskers”

Andrew K. Schulz, Lena V. Kaufmann, Lawrence T. Smith, Deepti S. Philip, Hilda David, Jelena Lazovic, Michael Brecht, Gunther Richter, Katherine J. Kuchenbecker

http://www.science.org/doi/10.1126/science.adx8981

 

HKUST develops novel calcium-ion battery technology enhancing energy storage efficiency and sustainability



Breakthrough overcomes technical bottlenecks and accelerates green energy transition




Hong Kong University of Science and Technology

Prof. Yoonseob KIM (right), Associate Professor in the Department of Chemical and Biological Engineering and the study’s corresponding author, and his PhD student YIN Zhuoyu (left), the study’s first author. 

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Prof. Yoonseob KIM (right), Associate Professor in the Department of Chemical and Biological Engineering and the study’s corresponding author, and his PhD student YIN Zhuoyu (left), the study’s first author, who is holding an electrochemical cell mold. They are pictured beside a battery cell cycler.

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Credit: HKUST





Researchers at The Hong Kong University of Science and Technology (HKUST) have achieved a breakthrough in calcium-ion battery (CIB) technology, which could transform energy storage solutions in everyday life. Utilizing quasi-solid-state electrolytes (QSSEs), these innovative CIBs promise to enhance the efficiency and sustainability of energy storage, impacting a wide range of applications from renewable energy systems to electric vehicles. The findings are published in the international journal Advanced Science titled “High-Performance Quasi-Solid-State Calcium-Ion Batteries from Redox-Active Covalent Organic Framework Electrolytes”.

The urgency for sustainable energy storage solutions is growing critical worldwide. As the world accelerates its shift to green energy, the demand for efficient and stable battery systems has never been more pressing. Today’s mainstream lithium-ion batteries (LIBs) face challenges due to resource scarcity and near-limited energy density, making the exploration of alternatives like CIBs essential for a sustainable future.

CIBs hold great promise due to their electrochemical window comparable to that of LIBs and their abundance on Earth. However, they have struggles, particularly in achieving efficient cation transport and maintaining stable cycling performance. These obstacles currently limit the competitiveness of CIBs against commercially available LIBs.

To overcome these challenges, the research team led by Prof. Yoonseob KIM, Associate Professor of the Department of Chemical and Biological Engineering at HKUST, has developed redox covalent organic frameworks to serve as QSSEs. These carbonyl-rich QSSEs demonstrated remarkable ionic conductivity (0.46 mS cm–1) and Ca2+ transport capability (>0.53) at room temperature. Combining experimental and simulation studies, the team revealed that Ca2+ rapidly transports along the aligned carbonyl groups within the ordered COFs pores.

This innovative approach led to the creation of a full calcium-ion cell that exhibited a reversible specific capacity of 155.9 mAh g–1 at 0.15 A g–1 and maintained over 74.6% capacity retention at 1 A g–1 after 1,000 cycles, showcasing the potential of redox COFs to advance CIB technology.

Prof. Kim said, "Our research highlights the transformative potential of calcium-ion batteries as a sustainable alternative to lithium-ion technology. By leveraging the unique properties of redox covalent organic frameworks, we have taken a significant step towards realizing high-performance energy storage solutions that can meet the demands of a greener future."

This study was a collaboration between researchers at HKUST and Shanghai Jiao Tong University.

 

How much can an autonomous robotic arm feel like part of the body



Humanlike speed maximizes ownership, usability and social perception



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Toyohashi University of Technology (TUT)

Figure 1: Concept image of an autonomous prosthetic arm 

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 In virtual reality, participants embodied an avatar whose left forearm was replaced by an autonomous prosthetic arm that flexed toward a target at different movement speeds.

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Credit: COPYRIGHT(C)TOYOHASHI UNIVERSITY OF TECHNOLOGY. ALL RIGHTS RESERVED.





Summary

When AI powered prosthetic arms that move autonomously become widespread, understanding how people feel about them and accept them will be crucial. In this study, we used virtual reality to simulate a situation in which a participant’s own arm was replaced by a robotic prosthetic arm, and examined how the prosthesis movement speed affects embodiment, including body ownership, the sense of agency, usability, and social impressions of the robot such as competence and discomfort. We found that both overly fast and overly slow movements reduced body ownership and usability, whereas a moderate speed close to natural human reaching, with a movement duration of about one second, produced the most positive impressions.

Contents

When a person loses a hand or arm, prosthetic limbs are essential technologies for maintaining everyday function. To date, much prosthetics research has focused on control methods that enable the device to move according to the user’s intention, often by using biosignals such as electromyography (EMG) and electroencephalography (EEG), and on improving the accuracy of such control. Meanwhile, advances in machine learning and AI are making it increasingly realistic that future prostheses will assess the situation and provide assistance through autonomous or semi-autonomous movements. However, when a body part moves independently of one’s will, people are likely to experience it as “unsettling” or “not part of my body,” creating a major barrier to acceptance.

Addressing this issue, prior work has suggested that even if a limb moves on its own, discomfort can be reduced and acceptance as part of the body can increase when the movement’s goal or intention is understandable. Building on this idea, Harin Manujaya Hapuarachchi and his colleagues (Hapuarachchi was a doctoral student at the time of the study and is now an Assistant Professor in the School of Informatics at Kochi University of Technology) focused on movement speed. In virtual reality, we presented an avatar whose left forearm was replaced with a prosthetic limb, and participants performed a reaching task. The prosthetic arm (a virtual forearm) autonomously flexed toward a target, and we systematically varied its movement duration across six levels (125 ms to 4 s). After each condition, participants rated body ownership, sense of agency, usability (SUS), and social impressions of the robot (RoSAS: competence, warmth, and discomfort).

The results were clear.

• At a moderate speed (movement duration of 1 s), body ownership, agency, and usability were highest.

• In the fastest (125 ms) and slowest (4 s) conditions, body ownership, agency, and usability were significantly lower.

• Perceived competence was higher at moderate to slightly faster speeds, whereas discomfort was highest in the fastest condition. Warmth did not show a clear dependence on speed.

These findings indicate that, in a future where AI enabled prostheses provide autonomous assistance, it is not sufficient to pursue faster and more accurate performance alone. Instead, movement speed should be designed to match what people can readily accept as part of their own body.

The insights may inform not only the design of autonomous prosthetic arms, but also other forms of robotic body augmentation, such as supernumerary robotic limbs, exoskeletons, and wearable robots, that operate as functional extensions of the body.

Looking ahead, we will also examine adaptation and learning through long-term use. People can come to experience familiar tools as if they were part of their body. If a fast and accurate robotic body part is used continuously in daily life, it may become “normal,” feel easier to use, and be more readily embodied.

Finally, using VR is important because it allows researchers to safely simulate prosthetic technologies and control schemes that are not yet widely available, enabling the psychological, acceptance-related, and design requirements to be evaluated in advance.

Funding agency:

This research was supported by JSPS KAKENHI (JP22KK0158), the Murata Science and Education Foundation, JST (JPMJFS121), and MEXT (202334Z302).

Reference:

Hapuarachchi, H., Inoue, Y., Shigemasu, H., & Kitazaki, M. (2026).

Movement speed of an autonomous prosthetic limb shapes embodiment, usability and robotic social attributes in virtual reality.

Scientific Reports (Published: 07 February 2026).

DOI: 10.1038/s41598-026-38977-8


A physical pole was placed in front of the participant and matched in VR to prevent direct reaching and to ensure that target acquisition relied on the prosthetic arm flexion.

Credit

COPYRIGHT(C)TOYOHASHI UNIVERSITY OF TECHNOLOGY. ALL RIGHTS RESERVED.