Recent research has confirmed that our fingers can detect the presence of objects buried in sand: via sensing subtle vibrational changes.

Recent research has uncovered a surprising sensory ability in humans that is little known.

The sense of touch humans possess actually includes the ability to detect the presence of objects buried in granular material (such as sand), by sensing the way an object affects vibration characteristics of the sand. This requires no direct contact with the object, and has been observed to be effective at a median distance of up to 6.9cm.

This capability, documented for the first time in humans by researchers at Queen Mary University of London and University College London, parallels what some shorebirds, such as sandpipers and plovers, use to locate prey hidden under sand through subtle mechanical cues.

In human experiments, participants gently moved their fingers through sand and successfully sensed hidden cubes before touching them, achieving about 70.7% precision. This sensitivity approaches the theoretical physical limit of detecting minute mechanical disturbances created by objects beneath the sand.​

Called “Remote touch”, the extra dimension of the human sense of touch works by perceiving tiny mechanical “reflections” (vibrations) in the granular medium caused by sand displacement near a buried object’s stable surface. Typically, detection occurred at a median distance of 2.7 centimeters, with a maximum range near 6.9 centimeters predicted by granular physics. This expanded form of touch challenges the conventional notion that human tactile perception is only proximal — limited to direct skin contact — and suggests a broader perceptual “receptive field”.​

The researchers have also compared human ability to a robotic tactile sensor trained with a neural network. Although robotics detected objects from slightly farther distances, the finding have shown lower overall precision (around 40%) due to frequent false positives. This highlights human sensory systems’ fine-tuning and efficiency for remote tactile perception.​

Beyond redefining touch, this discovery offers practical implications for robotics and exploration technologies where vision is limited. Insights from human remote touch can inspire more sensitive robotic systems and assistive tools for applications like archaeological excavation, planetary surface exploration, and underwater tasks, ultimately enhancing humans’ interaction with challenging environments.