3D printing approach for shape-changing materials means better biomedical, energy, robotics devices

Celebrity Gig
a) Magnetic particles dispersed in solvent to show magnetic field orientations of the main Halbach array. b) Magnetic field shown for alternate Halbach array configuration. Credit: Advanced Materials (2024). DOI: 10.1002/adma.202414209

An Oregon State University researcher has helped create a new 3D printing approach for shape-changing materials that are likened to muscles, opening the door for improved applications in robotics as well as biomedical and energy devices.

The liquid crystalline elastomer structures printed by Devin Roach of the OSU College of Engineering and collaborators can crawl, fold and snap directly after printing. The study is published in the journal Advanced Materials.

“LCEs are basically soft motors,” said Roach, assistant professor of mechanical engineering. “Since they’re soft, unlike regular motors, they work great with our inherently soft bodies. So they can be used as implantable medical devices, for example, to deliver drugs at targeted locations, as stents for procedures in target areas, or as urethral implants that help with incontinence.”

Liquid crystalline elastomers are lightly crosslinked polymer networks that are able to change shape significantly upon exposure to certain stimuli, like heat. They can be used to transfer thermal energy, such as from the sun or alternating currents, into mechanical energy that can be stored and used on demand. LCEs can also play a big role in the field of soft robotics, Roach added.

READ ALSO:  KWAM 1 responds to incident at Lagos polling unit, allegations of taking polling materials to his house

“Flexible robots incorporating LCEs could explore areas that are unsafe or unfit for humans to go,” he said. “They have also been shown to have promise in aerospace as actuators for automated systems such as those for deep space grappling, radar deployment or extraterrestrial exploration.”







The liquid crystalline elastomer structures printed by Devin Roach of the OSU College of Engineering and collaborators can crawl, fold and snap directly after printing. Credit: OSU College of Engineering

Underpinning the functional utility of liquid crystalline elastomers is their blend of anisotropy and viscoelasticity, Roach said.

Anisotropy refers to the property of being directionally dependent, such as how wood is stronger along the grain than across it, and viscoelastic materials are both viscous—like honey, which resists flow and deforms slowly under stress—and elastic, returning to their original shape when the stress is removed, like rubber. Viscoelastic materials slowly deform and gradually recover.

Liquid crystalline elastomers’ shape-changing properties are dependent on the alignment of the molecules within the materials. Roach and collaborators at Harvard University, the University of Colorado, and Sandia and Lawrence Livermore national laboratories discovered a way to align the molecules using a magnetic field during a type of 3D printing called digital light processing.

READ ALSO:  Trump stock tumbles after buoyant debut

Also known as additive manufacturing, 3D printing allows for the creation of objects one layer at a time. In digital light processing, light is used to harden liquid resin into solid shapes with precision. However, getting the elastomers’ molecules aligned can be challenging.

“Aligning the molecules is the key to unlocking the LCEs’ full potential and enabling their use in advanced, functional applications,” Roach said.

Roach and the other researchers varied the strength of the magnetic field and studied how it and other factors, such as the thickness of each printed layer, affected molecular alignment. This enabled them to print complicated liquid crystalline elastomer shapes that change in specific ways when heated.

“Our work opens up new possibilities for creating advanced materials that respond to stimuli in useful manners, potentially leading to innovations in multiple fields,” Roach said.

In related research published in Advanced Engineering Materials, Roach led a team of Oregon State students and collaborators at Sandia, Lawrence Livermore and Navajo Technical University in exploring the mechanical damping potential of liquid crystalline elastomers.

Mechanical damping refers to reducing or dissipating the energy of vibrations or oscillations in mechanical systems, including automotive shock absorbers, seismic dampers that help protect buildings from earthquakes, and vibration dampers on bridges that minimize oscillations caused by wind or motor vehicles.

READ ALSO:  US says Google saw ad startup as a 'threat'—and bought it

OSU students Adam Bischoff, Carter Bawcutt and Maksim Sorkin and the other researchers demonstrated that a fabrication method known as direct ink write 3D printing can produce mechanical damping devices that effectively dissipate energy across a wide range of loading rates.

More information:
Jeremy A. Herman et al, Digital Light Process 3D Printing of Magnetically Aligned Liquid Crystalline Elastomer Free–forms, Advanced Materials (2024). DOI: 10.1002/adma.202414209

Adam Bischoff et al, Monodomain Liquid‐Crystal Elastomer Lattices for Broad Strain‐Rate Mechanical Damping, Advanced Engineering Materials (2024). DOI: 10.1002/adem.202401796

Provided by
Oregon State University


Citation:
3D printing approach for shape-changing materials means better biomedical, energy, robotics devices (2024, December 2)
retrieved 2 December 2024
from

This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no
part may be reproduced without the written permission. The content is provided for information purposes only.

Categories

Share This Article
Leave a comment