From light fueled self-oscillators to light communicating material networks

ERC (European Research Council)HORIZON-ERCID: 101076207
EC Contribution
€14,955
Consortium Size
1 orgs
Start Year
2023
Summary

ONLINE aims to develop new concepts of communication between inanimate materials.What is meant by communication? In biological context, communication refers to interactive behaviour of one organism affecting the current or future behaviour of another. In the context of bioinspired materials, ONLINE will develop life-like material structures that communicate with each other via physical contact, fluidic medium, or optical beams. These inanimate materials will be coupled to form networks that communicate autonomously through light.How to make them? The core concept behind the communicative materials is self-oscillatory (self-sustained) motions in light-responsive liquid crystal elastomers (LCEs). Self-oscillation is a responsive structure that can self-sustain its own mechanical motion in a constant energy field. It captures the key concepts of living organisms, i.e., functioning out of thermodynamic equilibrium and energy dissipation. My goal is to scale down the self-oscillator concepts to the micro-scale and realize soft material robots that can communicate.Why is this important? There exists an increasing need for artificial materials that can interact, alike biological systems. However, all the dynamic features of state-of-the-art responsive materials are based on internal material properties, and making individual materials interact with each other is a huge challenge. ONLINE proposes three new model systems for material communication: (I) Microscopic walker swarm, in which the locomotion and patterns of interactions between individuals can be fully programmed; (II) Cilia array that move cooperatively and self-regulate the fluidics at low Reynolds numbers; (III) Homeostasis-like light-communicating coupled network that provides a full set of tunable parameters to mimic the complexity of biological oscillators.

Consortium (1)

Project Results (10)

Source: CORDIS, the EU research results database.

Publications (9)
A light-fueled self-oscillator that senses force
Communications Materials· 2025DOI
Zixuan Deng, Arri Priimagi, Kai Li, Hao Zeng
Emergent Locomotion in Self‐Sustained, Mechanically Connected Soft Matter Rings
Advanced Materials· 2025DOI
Hongshuang Guo; Kai Li; Arri Priimagi; Hao Zeng
Feedback regulated opto-mechanical soft robotic actuators
Cell Reports Physical Science· 2025DOI
Jianfeng Yang, Haotian Pi, Zixuan Deng, Hongshuang Guo, Wan Shou, Hang Zhang, Hao Zeng
Magneto-Photochemically Responsive Liquid Crystal Elastomer for Underwater Actuation
ACS Applied Materials & Interfaces· 2025DOI
Yasaman Nemati, Qi Yang, Fereshteh Sohrabi, Jaakko V. I. Timonen, Carlos Sánchez-Somolinos, Mari Honkanen, Hao Zeng, Arri Priimagi
Nature Communications
Nature Communications· 2024DOI
Jianfeng Yang; M. Ravi Shankar; Hao Zeng
Nature Materials
Nature Materials· 2024DOI
Zixuan Deng; Kai Li; Arri Priimagi; Hao Zeng
A Scalable, Incoherent‐Light‐Powered, Omnidirectional Self‐Oscillator
Advanced Intelligent Systems· 2023DOI
Nemati, Y; Deng, ZX; Pi, HT; Guo, HS; Zhang, H; Priimagi, A; Zeng; H
Angewandte Chemie - International Edition
Angewandte Chemie· 2023DOI
Guo, Hongshuang; Liang, Chen; Ruoko, Tero Petri; Meteling, Henning; Peng, Bo; Zeng, Hao; Priimagi; Arri
Bright and Switchable Whiteness in Macro‐Crosslinked Hydrogels
Advanced Optical Materials· 2023DOI
Amanda Eklund; Shanming Hu; Yuhuang Fang; Henri Savolainen; Haotian Pi; Hao Zeng; Arri Priimagi; Olli Ikkala; Hang Zhang
Other Results (1)
Periodic Reporting for period 1 - ONLINE (From light fueled self-oscillators to light communicating material networks)