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Main Authors: Jeggle, Julian, Rüschenbaum, Matthias, Paskert, Adrian, Kalthoff, Ivan, Vinnemeier, Elena, Schönfelder, Jesco, Imbrock, Jörg, Denz, Cornelia, Rey, Marcel, Wittkowski, Raphael
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.14917
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author Jeggle, Julian
Rüschenbaum, Matthias
Paskert, Adrian
Kalthoff, Ivan
Vinnemeier, Elena
Schönfelder, Jesco
Imbrock, Jörg
Denz, Cornelia
Rey, Marcel
Wittkowski, Raphael
author_facet Jeggle, Julian
Rüschenbaum, Matthias
Paskert, Adrian
Kalthoff, Ivan
Vinnemeier, Elena
Schönfelder, Jesco
Imbrock, Jörg
Denz, Cornelia
Rey, Marcel
Wittkowski, Raphael
contents Active colloidal microparticles require reliable actuation to sustain directed motion. Light-based propulsion is particularly attractive as it provides persistent energy supply and enables direct spatiotemporal control. Here, we introduce 3D-printable particles with symmetry-broken refractive index profiles (SBRIP particles) that achieve propulsion through direct momentum transfer from asymmetric light refraction. Internal refractive-index gradients provide optical symmetry breaking independent of external shape, fundamentally decoupling propulsion from particle geometry. Geometrically symmetry-broken particles with a homogeneous refractive index are another special case, where propulsion originates from refractive contrast at the boundary instead of within the particle. Unlike conventional systems relying on absorption or reflection, this transparency-based mechanism minimizes heating and mitigates shadowing in bulk suspensions. We present a theoretical framework for refractive propulsion as well as numerical simulations of the SBRIP particles using raytracing and the finite volume method. This is complemented by experiments, validating the momentum transfer mechanism using particles with geometric symmetry breaking. The high transparency of our particles ensures deep light penetration, enabling the realization of volumetric active matter. This opens pathways toward adaptive nonlinear optical materials where light-driven particle reorganization modulates the local refractive index, establishing a dynamic feedback loop between the optical field and the material structure.
format Preprint
id arxiv_https___arxiv_org_abs_2604_14917
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Light-propelled microparticles based on symmetry-broken refractive index profiles
Jeggle, Julian
Rüschenbaum, Matthias
Paskert, Adrian
Kalthoff, Ivan
Vinnemeier, Elena
Schönfelder, Jesco
Imbrock, Jörg
Denz, Cornelia
Rey, Marcel
Wittkowski, Raphael
Optics
Mesoscale and Nanoscale Physics
Materials Science
Soft Condensed Matter
Active colloidal microparticles require reliable actuation to sustain directed motion. Light-based propulsion is particularly attractive as it provides persistent energy supply and enables direct spatiotemporal control. Here, we introduce 3D-printable particles with symmetry-broken refractive index profiles (SBRIP particles) that achieve propulsion through direct momentum transfer from asymmetric light refraction. Internal refractive-index gradients provide optical symmetry breaking independent of external shape, fundamentally decoupling propulsion from particle geometry. Geometrically symmetry-broken particles with a homogeneous refractive index are another special case, where propulsion originates from refractive contrast at the boundary instead of within the particle. Unlike conventional systems relying on absorption or reflection, this transparency-based mechanism minimizes heating and mitigates shadowing in bulk suspensions. We present a theoretical framework for refractive propulsion as well as numerical simulations of the SBRIP particles using raytracing and the finite volume method. This is complemented by experiments, validating the momentum transfer mechanism using particles with geometric symmetry breaking. The high transparency of our particles ensures deep light penetration, enabling the realization of volumetric active matter. This opens pathways toward adaptive nonlinear optical materials where light-driven particle reorganization modulates the local refractive index, establishing a dynamic feedback loop between the optical field and the material structure.
title Light-propelled microparticles based on symmetry-broken refractive index profiles
topic Optics
Mesoscale and Nanoscale Physics
Materials Science
Soft Condensed Matter
url https://arxiv.org/abs/2604.14917