What is the device and how does it generate electricity?

The device, called the Intrusion–Extrusion Triboelectric Nanogenerator (IE-TENG), converts the mechanical action of water forced under pressure into hydrophobic nanopores in a conductive silicon monolith into electrical energy. Charge transfer occurs at the solid–liquid interface as water enters and exits the pores, with frictional interactions producing a net electron transfer and an observable electrical output.

What efficiency is reported and how significant is it?

The reported energy conversion efficiency is about 9% for this solid–liquid configuration, among the highest values reported for similar nanogenerators. The researchers achieved this by engineering silicon monoliths with conductivity, defined nanoporous architecture, and a hydrophobic surface to control water motion inside the pores and stabilize the energy conversion process.

What potential applications are described in the study?

Potential applications include water-detection systems, wearable biometric sensors and smart garments, athletic performance monitors, as well as haptic robotics and touch-driven sensors. Because the device converts mechanical motion of liquid directly into an electrical signal, it may enable self-powered sensors in environments where conventional power sources are impractical.

Engineered Silicon Nanopores Generate Electricity from Water Movement

Q: What materials and reproducibility aspects are emphasized?

The approach relies on abundant materials—silicon and water—rather than rare or exotic components, a point the researchers emphasize to highlight reproducibility and potential scalability. Achieving a material design that combines conductivity, nanoporous structure, and hydrophobicity was identified as a critical fabrication challenge that the team addressed in their process.

Science By James Lawson Nov 14, 2025 08:19

Engineered Silicon Nanopores Generate Electricity from Water Movement

Researchers report a triboelectric nanogenerator that harvests electricity from water forced into and out of hydrophobic nanopores in silicon, achieving about 9% energy conversion and showing potential for scalable, reproducible devices.

Researchers at Deutsches Elektronen-Synchrotron (DESY) and Hamburg University of Technology (TUHH), with collaborators at CIC energiGUNE and the University of Ferrara, have demonstrated a triboelectric nanogenerator that converts the mechanical action of water entering and exiting nanopores into usable electrical energy.

How the device works

The device, described as an Intrusion–Extrusion Triboelectric Nanogenerator (IE-TENG), exploits charge transfer at the solid–liquid interface. When water is forced under pressure into hydrophobic nanopores in a conductive silicon monolith and then expelled, frictional interactions at the interface produce a net electron transfer and an electrical output. The researchers compare the basic effect to the familiar generation of static electricity, such as when walking across a carpet and receiving a small shock when touching a metal doorknob.

Design and performance

The team engineered silicon monoliths with a combination of conductivity, defined nanoporous architecture, and hydrophobic surface properties to control water motion inside the pores and stabilize the energy conversion process. The reported energy conversion efficiency is about 9% for this solid–liquid configuration, which the authors say is among the highest values reported for similar nanogenerators.

Materials and reproducibility

Investigators highlight that the approach uses abundant materials—silicon and water—rather than rare or exotic components, which they say improves reproducibility and supports potential scalability. Achieving a material design that is simultaneously conductive, nanoporous, and hydrophobic was identified as a critical challenge that the team addressed in their fabrication process.

Potential applications

water-detection systems
wearable biometric sensors and smart garments
athletic performance monitors
haptic robotics and touch-driven sensors

Because the device converts mechanical motion of liquid directly into electrical signal, it may enable self-powered sensors in environments where conventional power sources are impractical.

Publication

Contributors

James Lawson

Investigative science and tech reporter focusing on AI, space industry and quantum breakthroughs

University College London (UCL) • United Kingdom