Publication detail
Nanodroplet Flight Control in Electrohydrodynamic Redox 3D Printing
MENÉTREY, M. ZEZULKA, L. FANDRÉ, P. SCHMID, F. SPOLENAK, R.
English title
Nanodroplet Flight Control in Electrohydrodynamic Redox 3D Printing
Type
journal article in Web of Science
Language
en
Original abstract
Electrohydrodynamic 3D printing is an additive manufacturing technique with enormous potential in plasmonics, microelectronics, and sensing applications thanks to its broad material palette, high voxel deposition rate, and compatibility with various substrates. However, the electric field used to deposit material is concentrated at the depositing structure, resulting in the focusing of the charged droplets and geometry-dependent landing positions, which complicates the fabrication of complex 3D shapes. The low level of concordance between the design and printout seriously impedes the development of electrohydrodynamic 3D printing and rationalizes the simplicity of the designs reported so far. In this work, we break the electric field centrosymmetry to study the resulting deviation in the flight trajectory of the droplets. Comparison of experimental outcomes with predictions of an FEM model provides new insights into the droplet characteristics and unveils how the product of droplet size and charge uniquely governs its kinematics. From these insights, we develop reliable predictions of the jet trajectory and allow the computation of optimized printing paths counterbalancing the electric field distortion, thereby enabling the fabrication of geometries with unprecedented complexity.
English abstract
Electrohydrodynamic 3D printing is an additive manufacturing technique with enormous potential in plasmonics, microelectronics, and sensing applications thanks to its broad material palette, high voxel deposition rate, and compatibility with various substrates. However, the electric field used to deposit material is concentrated at the depositing structure, resulting in the focusing of the charged droplets and geometry-dependent landing positions, which complicates the fabrication of complex 3D shapes. The low level of concordance between the design and printout seriously impedes the development of electrohydrodynamic 3D printing and rationalizes the simplicity of the designs reported so far. In this work, we break the electric field centrosymmetry to study the resulting deviation in the flight trajectory of the droplets. Comparison of experimental outcomes with predictions of an FEM model provides new insights into the droplet characteristics and unveils how the product of droplet size and charge uniquely governs its kinematics. From these insights, we develop reliable predictions of the jet trajectory and allow the computation of optimized printing paths counterbalancing the electric field distortion, thereby enabling the fabrication of geometries with unprecedented complexity.
Keywords in English
electrostatic deflection; autofocusing effect; charged droplet; correctedprinting path; electrohydrodynamicredox 3D printing
Released
29.12.2023
Publisher
AMER CHEMICAL SOC
Location
WASHINGTON
ISSN
1944-8244
Volume
16
Number
1
Pages from–to
1283–1292
Pages count
10
BIBTEX
@article{BUT187335,
author="Maxence {Menétrey} and Lukáš {Zezulka},
title="Nanodroplet Flight Control in Electrohydrodynamic Redox 3D Printing",
year="2023",
volume="16",
number="1",
month="December",
pages="1283--1292",
publisher="AMER CHEMICAL SOC",
address="WASHINGTON",
issn="1944-8244"
}