Saved in:
Bibliographic Details
Main Authors: Kleine, Melissa, Horodynski, Michael, Rotter, Stefan, Amarouchene, Yacine, Louyer, Yann, Perrin, Mathias, Bachelard, Nicolas
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2504.20702
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866915265812365312
author Kleine, Melissa
Horodynski, Michael
Rotter, Stefan
Amarouchene, Yacine
Louyer, Yann
Perrin, Mathias
Bachelard, Nicolas
author_facet Kleine, Melissa
Horodynski, Michael
Rotter, Stefan
Amarouchene, Yacine
Louyer, Yann
Perrin, Mathias
Bachelard, Nicolas
contents Optically-levitated nanoparticles in vacuum offer a pristine platform for high-quality mechanical oscillators, enabling a wide range of precision measurements and quantum technologies. A key performance metric in such systems is the stiffness of the optical trap, which is typically enhanced by increasing laser power-at the cost of unwanted heating, reduced coherence, and enhanced quantum backaction. Here, we demonstrate a fundamentally new route to increasing trap stiffness: wavefront shaping of the optical field. By tailoring the spatial phase profile of the trapping beam, we significantly boost the mechanical confinement of subwavelength particles without raising the optical intensity. Remarkably, this enhancement arises from a selective reduction of non-conservative optical forces, while preserving the conservative restoring forces that define trap stiffness. As a result, mechanical nonlinearities are also reduced, improving stability at low pressures. Our findings challenge the long-standing assumption that diffraction-limited focusing is optimal for dipolar Rayleigh particles, and establish wavefront shaping as a powerful, readily applicable tool to control optomechanical forces in levitation experiments. This opens new avenues for minimizing backaction, reducing thermal decoherence, and expanding the range of materials that can be stably levitated.
format Preprint
id arxiv_https___arxiv_org_abs_2504_20702
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Wavefront Shaping of Scattering Forces Enhances Optical Trapping of Levitated Nanoparticles
Kleine, Melissa
Horodynski, Michael
Rotter, Stefan
Amarouchene, Yacine
Louyer, Yann
Perrin, Mathias
Bachelard, Nicolas
Optics
Optically-levitated nanoparticles in vacuum offer a pristine platform for high-quality mechanical oscillators, enabling a wide range of precision measurements and quantum technologies. A key performance metric in such systems is the stiffness of the optical trap, which is typically enhanced by increasing laser power-at the cost of unwanted heating, reduced coherence, and enhanced quantum backaction. Here, we demonstrate a fundamentally new route to increasing trap stiffness: wavefront shaping of the optical field. By tailoring the spatial phase profile of the trapping beam, we significantly boost the mechanical confinement of subwavelength particles without raising the optical intensity. Remarkably, this enhancement arises from a selective reduction of non-conservative optical forces, while preserving the conservative restoring forces that define trap stiffness. As a result, mechanical nonlinearities are also reduced, improving stability at low pressures. Our findings challenge the long-standing assumption that diffraction-limited focusing is optimal for dipolar Rayleigh particles, and establish wavefront shaping as a powerful, readily applicable tool to control optomechanical forces in levitation experiments. This opens new avenues for minimizing backaction, reducing thermal decoherence, and expanding the range of materials that can be stably levitated.
title Wavefront Shaping of Scattering Forces Enhances Optical Trapping of Levitated Nanoparticles
topic Optics
url https://arxiv.org/abs/2504.20702