CVD Synthesis of 3D-Shaped 3D Graphene Using a 3D-Printed Nickel-PLGA Catalyst Precursor

Vamsi Krishna Reddy Kondapalli; Xingyu He; Mahnoosh Khosravifar; Safa Khodabakhsh; Boyce Collins; Sergey Yarmolenko; Ashley Paz Y Puente; Vesselin Shanov

doi:10.1021/acsomega.1c04072

CVD Synthesis of 3D-Shaped 3D Graphene Using a 3D-Printed Nickel-PLGA Catalyst Precursor

ACS Omega. 2021 Oct 22;6(43):29009-29021. doi: 10.1021/acsomega.1c04072. eCollection 2021 Nov 2.

Authors

Vamsi Krishna Reddy Kondapalli¹, Xingyu He², Mahnoosh Khosravifar¹, Safa Khodabakhsh¹, Boyce Collins³, Sergey Yarmolenko³, Ashley Paz Y Puente¹, Vesselin Shanov^{1

2}

Affiliations

¹ Department of Mechanical and Materials Engineering, University of Cincinnati, Cincinnati, Ohio 45221, United States.
² Department of Chemical and Environmental Engineering, University of Cincinnati, Cincinnati, Ohio 45221, United States.
³ Engineering Research Center for Revolutionizing Biomaterials, North Carolina A&T State University, IRC Building, Suite 242, Greensboro, North Carolina 27411, United States.

Abstract

Earlier, various attempts to develop graphene structures using chemical and nonchemical routes were reported. Being efficient, scalable, and repeatable, 3D printing of graphene-based polymer inks and aerogels seems attractive; however, the produced structures highly rely on a binder or an ice support to stay intact. The presence of a binder or graphene oxide hinders the translation of the excellent graphene properties to the 3D structure. In this communication, we report our efforts to synthesize a 3D-shaped 3D graphene (3D²G) with good quality, desirable shape, and structure control by combining 3D printing with the atmospheric pressure chemical vapor deposition (CVD) process. Direct ink writing has been used in this work as a 3D-printing technique to print nickel powder-PLGA slurry into various shapes. The latter has been employed as a catalyst for graphene growth via CVD. Porous 3D²G with high purity was obtained after etching out the nickel substrate. The conducted micro CT and 2D Raman study of pristine 3D²G revealed important features of this new material. The interconnected porous nature of the obtained 3D²G combined with its good electrical conductivity (about 17 S/cm) and promising electrochemical properties invites applications for energy storage electrodes, where fast electron transfer and intimate contact with the active material and with the electrolyte are critically important. By changing the printing design, one can manipulate the electrical, electrochemical, and mechanical properties, including the structural porosity, without any requirement for additional doping or chemical postprocessing. The obtained binder-free 3D²G showed a very good thermal stability, tested by thermo-gravimetric analysis in air up to 500 °C. This work brings together two advanced manufacturing approaches, CVD and 3D printing, thus enabling the synthesis of high-quality, binder-free 3D²G structures with a tailored design that appeared to be suitable for multiple applications.