Next-Generation Additive Manufacturing: Tailorable Graphene/Polylactic(acid) Filaments Allow the Fabrication of 3D Printable Porous Anodes for Utilisation within Lithium-ion Batteries

Foster, C; Zou, G; Jiang, Y; Down, M; Liauw, C; Ferrari, A; Ji, X; Smith, G; Kelly, P; Banks, C

doi:10.1002/batt.201800148

All Outputs (5)

Ni−Fe (Oxy)hydroxide Modified Graphene Additive Manufactured (3D‐Printed) Electrochemical Platforms as an Efficient Electrocatalyst for the Oxygen Evolution Reaction (2019)
Journal Article
dos Santos, P., Rowley-Neale, S., Ferrari, A., Bonacin, J., & Banks, C. (2019). Ni−Fe (Oxy)hydroxide Modified Graphene Additive Manufactured (3D‐Printed) Electrochemical Platforms as an Efficient Electrocatalyst for the Oxygen Evolution Reaction. ChemElectroChem, 6(22), 5633-5641. https://doi.org/10.1002/celc.201901541

We demonstrate that polylactic acid (PLA)/graphene additive manufactured (3D-printed) electrodes (Gr/AMEs) electrodeposited with Ni−Fe (oxy)hydroxide can efficiently catalyse the oxygen evolution reaction (OER). X-ray photoelectron spectroscopy (XPS)... Read More about Ni−Fe (Oxy)hydroxide Modified Graphene Additive Manufactured (3D‐Printed) Electrochemical Platforms as an Efficient Electrocatalyst for the Oxygen Evolution Reaction.

Investigating the Integrity of Graphene towards the Electrochemical Hydrogen Evolution Reaction (HER) (2019)
Journal Article
Ferrari, A., Brownson, D., & Banks, C. (2019). Investigating the Integrity of Graphene towards the Electrochemical Hydrogen Evolution Reaction (HER). Scientific Reports, 9, https://doi.org/10.1038/s41598-019-52463-4

Mono-, few-, and multilayer graphene is explored towards the electrochemical Hydrogen Evolution Reaction (HER). Careful physicochemical characterisation is undertaken during electrochemical perturbation revealing that the integrity of graphene is str... Read More about Investigating the Integrity of Graphene towards the Electrochemical Hydrogen Evolution Reaction (HER).

Exploring the reactivity of distinct electron transfer sites at CVD grown monolayer graphene through the selective electrodeposition of MoO2 nanowires (2019)
Journal Article
Ferrari, A., Foster, C., Brownson, D., Whitehead, K., & Banks, C. (2019). Exploring the reactivity of distinct electron transfer sites at CVD grown monolayer graphene through the selective electrodeposition of MoO2 nanowires. Scientific Reports, 9, https://doi.org/10.1038/s41598-019-48022-6

The origin of electron transfer at Chemical Vapour Deposition (CVD) grown monolayer graphene using a polymer-free transfer methodology is explored through the selective electrodeposition of Molybdenum (di)oxide (MoO2). The electrochemical decoration... Read More about Exploring the reactivity of distinct electron transfer sites at CVD grown monolayer graphene through the selective electrodeposition of MoO2 nanowires.

Cover Picture: Next-Generation Additive Manufacturing: Tailorable Graphene/Polylactic(acid) Filaments Allow the Fabrication of 3D Printable Porous Anodes for Utilisation within Lithium-Ion Batteries (Batteries & Supercaps 5/2019) (2019)
Other
Foster, C., Zou, G., Jiang, Y., Down, M., Liauw, C., Ferrari, A., …Banks, C. (2019). Cover Picture: Next-Generation Additive Manufacturing: Tailorable Graphene/Polylactic(acid) Filaments Allow the Fabrication of 3D Printable Porous Anodes for Utilisation within Lithium-Ion Batteries (Batteries & Supercaps 5/2019). [Image]

Next-Generation Additive Manufacturing: Tailorable Graphene/Polylactic(acid) Filaments Allow the Fabrication of 3D Printable Porous Anodes for Utilisation within Lithium-ion Batteries (2019)
Journal Article
Foster, C., Zou, G., Jiang, Y., Down, M., Liauw, C., Ferrari, A., …Banks, C. (2019). Next-Generation Additive Manufacturing: Tailorable Graphene/Polylactic(acid) Filaments Allow the Fabrication of 3D Printable Porous Anodes for Utilisation within Lithium-ion Batteries. #Journal not on list, 2(5), 448-453. https://doi.org/10.1002/batt.201800148

Herein, we report the fabrication and application of Li-ion anodes for utilisation within Li-ion batteries, which are fabricated via additive manufacturing/3D printing (fused deposition modelling) using a bespoke graphene/polylactic acid (PLA) filame... Read More about Next-Generation Additive Manufacturing: Tailorable Graphene/Polylactic(acid) Filaments Allow the Fabrication of 3D Printable Porous Anodes for Utilisation within Lithium-ion Batteries.