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Main Authors: Markovic, Menotti, Oberndorfer, Lucia, Krieger, Tobias M., Brytavskyi, Ievgen, Lehner, Barbara, Freund, Julia, Karunakaran, Vishnu Prakash, Domke, Matthias, Gangloff, Dorian, Schimpf, Christian, Michler, Peter, Portalupi, Simone Luca, Jetter, Michael, Trotta, Rinaldo, Martín-Sánchez, Javier, Rastelli, Armando, Dohnal, Fadi, Stroj, Sandra
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2601.09476
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author Markovic, Menotti
Oberndorfer, Lucia
Krieger, Tobias M.
Brytavskyi, Ievgen
Lehner, Barbara
Freund, Julia
Karunakaran, Vishnu Prakash
Domke, Matthias
Gangloff, Dorian
Schimpf, Christian
Michler, Peter
Portalupi, Simone Luca
Jetter, Michael
Trotta, Rinaldo
Martín-Sánchez, Javier
Rastelli, Armando
Dohnal, Fadi
Stroj, Sandra
author_facet Markovic, Menotti
Oberndorfer, Lucia
Krieger, Tobias M.
Brytavskyi, Ievgen
Lehner, Barbara
Freund, Julia
Karunakaran, Vishnu Prakash
Domke, Matthias
Gangloff, Dorian
Schimpf, Christian
Michler, Peter
Portalupi, Simone Luca
Jetter, Michael
Trotta, Rinaldo
Martín-Sánchez, Javier
Rastelli, Armando
Dohnal, Fadi
Stroj, Sandra
contents This article presents a novel fabrication route for miniaturized piezoelectric actuators that relies exclusively on processes based on femtosecond (fs) laser ablation. Previous work has already demonstrated that fs-lasers are uniquely suited for the fabrication of piezoelectric actuators based on PMN-PT, which are required for multiaxial strain-tuning of quantum dots (QDs) to enable, e.g. the generation of highly entangled photon pairs. Building on these foundations, the present work advances actuator performance and capabilities by introducing a local thinning strategy. This approach allows the realization of smaller devices, which in turn enables lower operating voltages, while simultaneously offering the possibility of integrating multiple quantum light sources on a single chip. The article provides a detailed description of the full fabrication chain, entirely based on fs-laser processing steps, from substrate thinning to metal layer structuring and final device definition. A particular focus is placed on the final cutting process, where the implementation of a third-harmonic ultraviolet (UV) fs-laser wavelength significantly improves edge quality and shape definition compared to the second harmonic (SH) wavelength used in previous work. The device fabricated through the combination of local thinning and UV-based cutting promises not only to enhance the efficiency of strain transfer but also to ensure the mechanical stability required for practical applications. These results establish fs-laser-based fabrication as a versatile and scalable method for next-generation piezoelectric actuators, paving the way for advanced strain-engineering approaches in semiconductor quantum optics and integrated quantum photonics.
format Preprint
id arxiv_https___arxiv_org_abs_2601_09476
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle A complete fs-laser-ablation route to miniaturized single-crystal PMN-PT piezoelectric actuators
Markovic, Menotti
Oberndorfer, Lucia
Krieger, Tobias M.
Brytavskyi, Ievgen
Lehner, Barbara
Freund, Julia
Karunakaran, Vishnu Prakash
Domke, Matthias
Gangloff, Dorian
Schimpf, Christian
Michler, Peter
Portalupi, Simone Luca
Jetter, Michael
Trotta, Rinaldo
Martín-Sánchez, Javier
Rastelli, Armando
Dohnal, Fadi
Stroj, Sandra
Applied Physics
Optics
This article presents a novel fabrication route for miniaturized piezoelectric actuators that relies exclusively on processes based on femtosecond (fs) laser ablation. Previous work has already demonstrated that fs-lasers are uniquely suited for the fabrication of piezoelectric actuators based on PMN-PT, which are required for multiaxial strain-tuning of quantum dots (QDs) to enable, e.g. the generation of highly entangled photon pairs. Building on these foundations, the present work advances actuator performance and capabilities by introducing a local thinning strategy. This approach allows the realization of smaller devices, which in turn enables lower operating voltages, while simultaneously offering the possibility of integrating multiple quantum light sources on a single chip. The article provides a detailed description of the full fabrication chain, entirely based on fs-laser processing steps, from substrate thinning to metal layer structuring and final device definition. A particular focus is placed on the final cutting process, where the implementation of a third-harmonic ultraviolet (UV) fs-laser wavelength significantly improves edge quality and shape definition compared to the second harmonic (SH) wavelength used in previous work. The device fabricated through the combination of local thinning and UV-based cutting promises not only to enhance the efficiency of strain transfer but also to ensure the mechanical stability required for practical applications. These results establish fs-laser-based fabrication as a versatile and scalable method for next-generation piezoelectric actuators, paving the way for advanced strain-engineering approaches in semiconductor quantum optics and integrated quantum photonics.
title A complete fs-laser-ablation route to miniaturized single-crystal PMN-PT piezoelectric actuators
topic Applied Physics
Optics
url https://arxiv.org/abs/2601.09476