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Metallic Ink for 3D Printing

This is a slightly modified version of an article written by Matt Shipman, Research Lead in University Communications.

Professor Michael Dickey holds an experimental device
Professor Michael Dickey holding an experimental device

Professor Michael Dickey and his colleagues have developed a metallic gel that is highly electrically conductive and can be used to print three-dimensional (3D) solid objects at room temperature.

“3D printing has revolutionized manufacturing, but we’re not aware of previous technologies that allowed you to print 3D metal objects at room temperature in a single step,” says Dickey, co-corresponding author of a paper on the work and the Camille & Henry Dreyfus Professor of Chemical and Biomolecular Engineering.“This opens the door to manufacturing a wide range of electronic components and devices.”

To create the metallic gel, the researchers start with a solution of micron-scale copper particles suspended in water. The researchers then add a small amount of an indium-gallium alloy that is liquid metal at room temperature. The resulting mixture is then stirred together.

Procedure to make metallic 3D ink

As the mixture is stirred, the liquid metal and copper particles essentially stick to each other, forming a metallic gel “network” within the aqueous solution.

“This gel-like consistency is important, because it means you have a fairly uniform distribution of copper particles throughout the material,” Dickey says. “This does two things. First, it means the network of particles connect to form electrical pathways. And second, it means that the copper particles aren’t settling out of solution and clogging the printer.”

The resulting gel can be printed using a conventional 3D printing nozzle and retains its shape when printed. And, when allowed to dry at room temperature, the resulting 3D object becomes even more solid while retaining its shape.

However, if users apply heat to the printed object while it is drying, some interesting things can happen.

Metallic ink gel particles imaged with (D) Scanning electron microscope and (E) Energy-dispersive X-ray spectroscopy
Metallic ink particles imaged with (D) Scanning electron microscope and (E) Energy-dispersive X-ray spectroscopy

The researchers found that the alignment of the particles influences how the material dries. For example, if you printed a cylindrical object, the sides would contract more than the top and bottom as it dries. If an object is drying at room temperature, the process is sufficiently slow that it doesn’t create structural change in the object. However, if you apply heat – for example, put it under a heat lamp at 80 degrees Celsius – the rapid drying can cause structural deformation. Because this deformation is predictable, you can make a printed object change shape after it is printed by controlling the pattern of the printed object and the amount of heat the object is exposed to while drying.

A video of the metallic gel printing and drying process is below:

“Ultimately, this sort of four-dimensional printing – the traditional three dimensions, plus time – is one more tool that can be used to create structures with the desired dimensions,” Dickey says. “But what we find most exciting about this material is its conductivity.

“Because the printed objects end up being as much as 97.5% metal, they are highly conductive. It’s obviously not as conductive as conventional copper wire, but it’s impossible to 3D print copper wire at room temperature. And what we’ve developed is far more conductive than anything else that can be printed. We’re pretty excited about the applications here.

“We’re open to working with industry partners to explore potential applications, and are always happy to talk with potential collaborators about future directions for research,” Dickey says.

The paper, “Metallic Gels for Conductive 3D and 4D Printing,” is published in the journal Matter. First author of the paper is Ruizhe Xing, a former visiting scholar with Prof. Dickey’s research group who is affiliated with Northwestern Polytechnical University and Tianjin University. Co-corresponding authors of the paper are Dickey, and Renliang Huang and Wei Qi of Tianjin University.

The paper was co-authored by Jiayi Yang, now at Xi’an University of Science and Technology; Dongguang Zhang, now at Taiyuan University of Technology; Wei Gong, now at the National University of Singapore; Taylor Neumann, a Ph.D. graduate from the Dickey group; Meixiang Wang and Jie Kong of Northwestern Polytechnical University. Jiayi Yang, Dongguang Zhang and Wei Gong, were visiting scholars with the Dickey group and Meixiang Wang is currently a postdoctoral researcher with the group.

The work was performed with support from the National Natural Science Foundation of China, under grant number 52203101; and from the China Scholarship Council, under grant number 201906250075.