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Main Authors: Mauron, Muriel, Vitanov, Lucie Castens, Michaud, César, Wenger, Raphaël, Muller, Nicolas, Nussbaumer, Roseline, Calvino, Céline, Weder, Christoph, Schrettl, Stephen, Gugler, Gilbert, Kiebala, Derek
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.17758
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author Mauron, Muriel
Vitanov, Lucie Castens
Michaud, César
Wenger, Raphaël
Muller, Nicolas
Nussbaumer, Roseline
Calvino, Céline
Weder, Christoph
Schrettl, Stephen
Gugler, Gilbert
Kiebala, Derek
author_facet Mauron, Muriel
Vitanov, Lucie Castens
Michaud, César
Wenger, Raphaël
Muller, Nicolas
Nussbaumer, Roseline
Calvino, Céline
Weder, Christoph
Schrettl, Stephen
Gugler, Gilbert
Kiebala, Derek
contents Inkjet printing technology achieves the precise deposition of liquid-phase materials via the digitally controlled formation of picoliter-sized droplets. Beyond graphical printing, inkjet printing has been employed for the deposition of separated drops on surfaces or the formation of continuous layers, which allows to construct materials gradients or periodic features that provide enhanced functionalities. Here, we explore the use of multinozzle, drop-on-demand piezoelectric inkjet technology for the manufacturing of mechanochromic materials, i.e., materials that change their color or fluorescence in response to mechanical deformation. To accomplish this, suitable polyurethane polymers of differing hardness grades were tested with a range of organic solvents to formulate low-viscosity, inkjet-printable solutions. Following their rheological characterization, two solutions comprised of "soft" and "hard" polyurethanes were selected for in-depth study. The solutions were imbibed with a mechanochromic additive to yield fluorescent inks, which were either dropcast onto polymeric substrates or printed to form checkerboard patterns of alternating hardness using a lab-built, multimaterial inkjet platform. Fluorescence imaging and spectroscopy were used to identify different hardness grades in the dropcast and printed materials, as well as to monitor the responses of these gradient materials to mechanical deformation. The insights gained in this study are expected to facilitate the development of inkjet-printable, mechanochromic polymer materials for a wide range of applications.
format Preprint
id arxiv_https___arxiv_org_abs_2401_17758
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Multimaterial Inkjet Printing of Mechanochromic Materials
Mauron, Muriel
Vitanov, Lucie Castens
Michaud, César
Wenger, Raphaël
Muller, Nicolas
Nussbaumer, Roseline
Calvino, Céline
Weder, Christoph
Schrettl, Stephen
Gugler, Gilbert
Kiebala, Derek
Applied Physics
Inkjet printing technology achieves the precise deposition of liquid-phase materials via the digitally controlled formation of picoliter-sized droplets. Beyond graphical printing, inkjet printing has been employed for the deposition of separated drops on surfaces or the formation of continuous layers, which allows to construct materials gradients or periodic features that provide enhanced functionalities. Here, we explore the use of multinozzle, drop-on-demand piezoelectric inkjet technology for the manufacturing of mechanochromic materials, i.e., materials that change their color or fluorescence in response to mechanical deformation. To accomplish this, suitable polyurethane polymers of differing hardness grades were tested with a range of organic solvents to formulate low-viscosity, inkjet-printable solutions. Following their rheological characterization, two solutions comprised of "soft" and "hard" polyurethanes were selected for in-depth study. The solutions were imbibed with a mechanochromic additive to yield fluorescent inks, which were either dropcast onto polymeric substrates or printed to form checkerboard patterns of alternating hardness using a lab-built, multimaterial inkjet platform. Fluorescence imaging and spectroscopy were used to identify different hardness grades in the dropcast and printed materials, as well as to monitor the responses of these gradient materials to mechanical deformation. The insights gained in this study are expected to facilitate the development of inkjet-printable, mechanochromic polymer materials for a wide range of applications.
title Multimaterial Inkjet Printing of Mechanochromic Materials
topic Applied Physics
url https://arxiv.org/abs/2401.17758