Periodic Reporting for period 1 - FLIP (Feedback Levitation on an Inverted Potential: A new tool for macroscopic quantum physics, sensing and information thermodynamics)
Période du rapport: 2023-05-01 au 2025-06-30
Controlling mesoscopic objects in the quantum regime is essential for advancing sensing, thermodynamics, and macroscopic quantum physics. Optical levitation has enabled key progress but remains limited by heating due to light absorption. This restricts the use of many materials and prevents certain quantum experiments.
The FLIP (Feedback Levitation on an Inverted Potential) project introduces a new approach that avoids optical confinement. By combining dark-field detection with active feedback control, it enables stable levitation and cooling without absorption. This makes it possible to control absorbing particles in high vacuum, such as those containing internal quantum degrees of freedom.
The project builds on recent advances in feedback-based ground-state cooling and aims to establish a new class of quantum control using dark and therefore unstable optical potentials for detection. It will allow quantum experiments with internally cold particles in free fall, enable sensing in non-conservative potentials, and make it possible to use absorbing particles like NV-doped nanodiamonds in levitated setups.
FLIP expands the range of systems that can be controlled in the quantum regime and provides new experimental platforms to study quantum states beyond the standard harmonic potential framework.
The FLIP (Feedback Levitation on an Inverted Potential) project introduces a new approach that avoids optical confinement. By combining dark-field detection with active feedback control, it enables stable levitation and cooling without absorption. This makes it possible to control absorbing particles in high vacuum, such as those containing internal quantum degrees of freedom.
The project builds on recent advances in feedback-based ground-state cooling and aims to establish a new class of quantum control using dark and therefore unstable optical potentials for detection. It will allow quantum experiments with internally cold particles in free fall, enable sensing in non-conservative potentials, and make it possible to use absorbing particles like NV-doped nanodiamonds in levitated setups.
FLIP expands the range of systems that can be controlled in the quantum regime and provides new experimental platforms to study quantum states beyond the standard harmonic potential framework.
The FLIP project aimed to implement levitation and control of mesoscopic particles using an inverted optical potential combined with active feedback, eliminating the need for trapping forces and therefore overcoming the absorption limitation in standard optical trapping. The primary technical objective was to demonstrate stable feedback-based confinement of a particle at the top of an unstable (anti-trapping) potential — a novel configuration enabling absorption-free control.
This goal was achieved during the project, culminating in the experimental demonstration of levitation on an inverted optical potential, as reported in a first publication. The study showed that a single nanoparticle can be stabilized and cooled in real time using measurement-based feedback alone, without relying on any conservative trapping potential.
This result represents a key milestone toward the full implementation of FLIP that would combine this stabilization scheme and a 'dark' detection in the intensity minimum in a higher gaussian mode light beam.
Additional technical developments during the project included upgrades to FPGA-based feedback systems to adapt to the experimental challenges of differentiating slow motion of the particle rolling down the inverted potential from other experimental drifts.
The project also participated in improving detection strategies under dark-field illumination, with the long term goal of detecting the particle motion in an intensity minimum to further mitigate the absorption.
This goal was achieved during the project, culminating in the experimental demonstration of levitation on an inverted optical potential, as reported in a first publication. The study showed that a single nanoparticle can be stabilized and cooled in real time using measurement-based feedback alone, without relying on any conservative trapping potential.
This result represents a key milestone toward the full implementation of FLIP that would combine this stabilization scheme and a 'dark' detection in the intensity minimum in a higher gaussian mode light beam.
Additional technical developments during the project included upgrades to FPGA-based feedback systems to adapt to the experimental challenges of differentiating slow motion of the particle rolling down the inverted potential from other experimental drifts.
The project also participated in improving detection strategies under dark-field illumination, with the long term goal of detecting the particle motion in an intensity minimum to further mitigate the absorption.
The main outcome of the project is the successful demonstration of feedback-based stabilization in an inverted optical potential, proving the core concept of the FLIP approach. This establishes a new regime for levitation, free from optical confinement and associated absorption, and opens the door to quantum experiments with a wider range of particle types and internal structures.
The next critical step is to demonstrate efficient optical detection in the intensity minimum of a higher-order optical mode, enabling position readout without absorption. Combining this with inverted-potential feedback in high vacuum will allow cooling to the quantum ground state in the FLIP configuration.
Further research is required to optimize the signal-to-noise ratio of the detection in the dark-field conditions and to ensure stable operation at ultra-low pressures. Long-term, this platform could support applications in quantum sensing, spin-mechanics, and foundational tests of quantum physics. Uptake of these results will depend on continued access to advanced optomechanical infrastructure, and collaborative research across experimental and theoretical groups.
The next critical step is to demonstrate efficient optical detection in the intensity minimum of a higher-order optical mode, enabling position readout without absorption. Combining this with inverted-potential feedback in high vacuum will allow cooling to the quantum ground state in the FLIP configuration.
Further research is required to optimize the signal-to-noise ratio of the detection in the dark-field conditions and to ensure stable operation at ultra-low pressures. Long-term, this platform could support applications in quantum sensing, spin-mechanics, and foundational tests of quantum physics. Uptake of these results will depend on continued access to advanced optomechanical infrastructure, and collaborative research across experimental and theoretical groups.