Batteries and Portable Power

Sculpting Conductive 3D Blocks with Graphene Foam

Rice University scientists have developed a simple way to produce conductive, three-dimensional objects made of graphene foam. The squishy solids look and feel something like a child’s toy but offer new possibilities for energy storage and flexible electronic sensor applications, according to Rice chemist James Tour.

The technique detailed in Advanced Materials is an extension of groundbreaking work by the Tour lab that produced the first laser-induced graphene (LIG) in 2014 by heating inexpensive polyimide plastic sheets with a laser.

The laser burns halfway through the plastic and turns the top into interconnected flakes of 2D carbon that remain attached to the bottom half. LIG can be made in macroscale patterns at room temperature.

The lab extended its technique to create LIG on wood and even food, but 3D objects of pure graphene were less practical until now, Tour said.

“Now we have built a prototype machine that lets us make graphene foam into 3D objects through automated successive layering and laser exposure,” Tour said. “This truly brings graphene into the third dimension without furnaces or the need for metal catalysts, and our process is easily scaled.”

The new method is based on laminated object manufacturing, in which layers of a material are assembled and then cut to shape. In this case, the bottom LIG layer remains attached to its polyimide base.

A second layer is coated with ethylene glycol and placed facedown on the first, like a jelly sandwich. Its polyimide top is then burned into graphene; the process is repeated until the block is complete.

Rice graduate student Duy Xuan Luong suspends a three-dimensional block of laser-induced graphene atop two willows. The lab uses an industrial laser to transform inexpensive polyimide plastic into graphene foam at room temperature, and then binds the sheets to produce lightweight, conductive 3D graphene.

Rice scientists are making 3D laser-induced graphene (LIG) foam through an automated process that begins by turning the top layer of a polyimide (PI) sheet into graphene (top), stacking another layer on top (center) with ethylene glycol (EG) as a binder and then burning the top layer’s PI into graphene as well (bottom). The process is repeated as necessary. Courtesy of the Tour Group

The ethylene glycol binder is evaporated away on a hot plate, and any remaining polyimide can be removed in a furnace. That leaves a pristine, spongy carbon block, said Duy Xuan Luong, a Rice graduate student and co-lead author of the paper.

The Rice lab stacked up to five layers of foam and then used a fiber-laser equipped commercial laser system to mill the block into complex shapes.

The lab assembled proof-of-concept lithium-ion capacitors that used 3D LIG as both anodes and cathodes. The anode’s gravimetric capacity of 354 milliamp hours per gram neared the theoretical limit of graphite, while the cathode’s capacity exceeded the average capacity of other carbon materials.

Full test cells retained about 70 percent of their capacity after 970 charge-discharge cycles.

“This is excellent performance in these new-generation lithium-ion capacitors, which capture the best properties of lithium-ion batteries and capacitor hybrids,” Tour said.

The researchers then infused a block of 3D LIG with liquid polydimethylsiloxane through its 20- to 30-nanometer pores. This created a stronger, still-flexible, conductive material without changing the original foam’s shape.

From this material, they made a flexible sensor that accurately recorded the pulse from the wrist of a volunteer and said further calibration of the device would let them extract blood pressure from the pulse waveform.

Rice University scientists have layered laser-induced graphene and built a prototype that shapes the resulting 3D blocks into sophisticated shapes. The foam offers new possibilities for energy storage and flexible electronic sensor applications. Courtesy of the Tour Group

Rice alumnus Ajay Subramanian is co-lead author of the paper. Co-authors are Rice graduate students Gladys Lopez Silva, Kaichun Yang, Peter Samora Owuor, Tuo Wang and Zhe Wang; former postdoctoral researcher Jongwon Yoon, now a senior researcher at the Korea Basic Science Institute; undergraduate Savannah Cofer; Jun Lou, a professor of materials science and nanoengineering; and Pulickel Ajayan, chair of Rice’s Department of Materials Science and NanoEngineering, the Benjamin M. and Mary Greenwood Anderson Professor in Engineering and a professor of chemistry.

The Air Force Office of Scientific Research and the Vietnam Education Foundation supported the research.

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