The team at Rice University utilized smart materials, machine learning, and an optical control system to create a soft robotic arm made from azobenzene liquid crystal elastomer. This type of polymer responds to light, allowing for precise motion control without the need for complex electronics or wiring.
The study, published in Advanced Intelligent Systems, showcases a robotic system that integrates a neural network trained to predict the light pattern required for specific arm movements. This advancement enables the robot to execute complex tasks autonomously, reducing the need for manual input.
Elizabeth Blackert, the lead author of the study and a Rice doctoral alumna, expressed the significance of this achievement: “This was the first demonstration of real-time, reconfigurable, automated control over a light-responsive material for a soft robotic arm.”
Unlike traditional rigid robots with limited mobility, soft robots like the one developed at Rice University offer a broader range of applications, especially in fields like medicine where gentle interactions are essential. Continuum robots, a category of soft robots, provide adaptive motion capabilities with increased degrees of freedom.
Dr. Hanyu Zhu, the materials scientist leading the research, emphasized the importance of interdisciplinary collaboration in developing such advanced soft robotics. The team’s unique blend of expertise in materials development, optical system design, and machine learning played a crucial role in achieving this milestone.
The novel elastomer created by the team responds rapidly to blue laser light, allowing for real-time control of the robotic arm. Unlike other light-sensitive materials, this elastomer reacts quickly to safer wavelengths, enabling precise and swift movements.
By utilizing a spatial light modulator to split a laser beam into multiple beamlets, the researchers were able to control different parts of the robotic arm independently. This approach provides the arm with the flexibility to bend and contract, mimicking the movements of an octopus tentacle. The potential for creating robots with unlimited degrees of freedom is vast, surpassing the capabilities of traditional robots with fixed joints.
Professor Rafael Verduzco, an expert in chemical and biomolecular engineering, highlighted the significance of using light patterns to achieve complex shape changes in soft robotics. This approach allows the material to adapt in multiple ways based on the laser beamlet pattern, providing versatility in robotic movements.
To train the robotic arm, the team utilized a convolutional neural network to analyze various light settings and corresponding arm deformations. This AI model can predict the precise light pattern required to achieve specific shapes or motions, such as flexing or reaching. While the current prototype operates in 2D, future iterations could expand into three dimensions with additional sensors and cameras.
Elizabeth Blackert emphasized the potential impact of this research on various applications, stating, “This is a step towards having safer, more capable robotics for implantable biomedical devices and industrial robots handling soft goods.”
More information:
Elizabeth R. Blackert et al, Spatiotemporally Controlled Soft Robotics with Optically Responsive Liquid Crystal Elastomers, Advanced Intelligent Systems (2025). DOI: 10.1002/aisy.202500045
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Light and AI drive precise motion in soft robotic arm (2025, June 9)
retrieved 9 June 2025
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