Tailored Error Mitigation for Single-Qubit Magnetometry

• URL: http://arxiv.org/abs/2512.11671v1
• Date: Fri, 12 Dec 2025 15:50:55 GMT
• Title: Tailored Error Mitigation for Single-Qubit Magnetometry
• Authors: Miriam Resch, Dennis Herb, Mirko Rossini, Joachim Ankerhold, Dominik Maile,
• Abstract summary: We present a novel mitigation technique for quantum sensors to efficiently reverse the effects of any noise.<n>We demonstrate that our method reaches the best achievable sensitivity in noisy single-NV-center magnetometry.
• Score: 0.0023109068197993757
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Quantum sensing is an emerging field with the potential to outperform classical methods in both precision and spatial resolution. However, the sensitivity of the underlying quantum platform also makes the sensors highly susceptible to their environmental noise. To address this issue, techniques from the field of quantum error mitigation use information about the noise to improve measurement results. We present a novel mitigation technique for quantum sensors to efficiently reverse the effects of any noise that can be described by a completely positive trace preserving map. The method leverages the knowledge acquired by a pre-characterization step of the device to automatically adapt to the complexity of the dissipative evolution and to indicate optimal sensing times $τ$ to achieve the most accurate results. We demonstrate that our method reaches the best achievable sensitivity in noisy single-NV-center magnetometry. This work marks a further step toward more resilient quantum sensors with the smallest scale of resolution.

Related papers

• Information-Scrambling-Enhanced Quantum Sensing Beyond the Standard Quantum Limit [24.972499920814034]
  We experimentally demonstrate a scalable, scrambling-enhanced quantum sensing protocol, implemented on a cross-shaped superconducting quantum processor.<n>By harnessing quantum information scrambling, the protocol converts local interactions into delocalized metrologically useful correlations, enabling robust signal amplification.<n>This work demonstrates a readily scalable path toward practical quantum sensing advantages with prevalent experimental platforms.
  arXiv  Detail & Related papers  (2025-12-24T13:05:34Z)
• Sequential analysis in a continuous spin-noise quantum sensor [32.505127447635864]
  We implement sequential data analysis techniques on a spin-noise-based quantum sensor.<n>Online protocols allow us to detect weak magnetic fields by adaptively collecting measurement data.<n>Our results demonstrate that sequential techniques enable faster and more sensitive detection, making them a powerful tool for quantum sensing.
  arXiv  Detail & Related papers  (2025-09-19T17:39:28Z)
• Non-Equilibrium Criticality-Enhanced Quantum Sensing with Superconducting Qubits [26.523015621022488]
  Exploiting quantum features allows for estimating external parameters with precisions well beyond the capacity of classical sensors.<n>Quantum criticality has been identified as a resource for achieving such enhancements with respect to the probe size.<n>Non-equilibrium probes harness dynamics, enabling quantum-enhanced precision with respect to time over a wide range of parameters.
  arXiv  Detail & Related papers  (2025-08-20T04:14:20Z)
• Adaptive Bayesian Single-Shot Quantum Sensing [35.355128149649666]
  In variational quantum sensing, a probe quantum system is generated via a parameterized quantum circuit.<n>This paper introduces an adaptive protocol that uses Bayesian inference to optimize the active information gain.
  arXiv  Detail & Related papers  (2025-07-22T11:35:27Z)
• Machine-Learning-Enhanced Entanglement Detection Under Noisy Quantum Measurements [0.5599792629509229]
  We introduce a machine-learning-based approach to achieve noise-resilient entanglement classification.<n>Our protocol significantly outperforms conventional methods in classification accuracy.<n>This work bridges machine learning and quantum information science, offering a practical tool for noise-robust quantum characterization.
  arXiv  Detail & Related papers  (2025-07-07T21:08:23Z)
• A Two-stage Optimization Method for Wide-range Single-electron Quantum Magnetic Sensing [24.34017006786999]
  Quantum magnetic sensing based on spin systems has emerged as a new paradigm for detecting ultra-weak magnetic fields with unprecedented sensitivity.<n>In this work, we report the design of a new protocol using a two-stage optimization method.<n>The proposed protocol is developed and evaluated in a challenging context of single-shot readout of an NV-center electron spin under a constrained total sensing time budget.
  arXiv  Detail & Related papers  (2025-06-16T13:28:32Z)
• Quantum Cramer-Rao Precision Limit of Noisy Continuous Sensing [0.6990493129893112]
  We establish a numerically efficient method to determine the quantum Cramer-Rao bound (QCRB) for continuously monitored quantum sensors subject to general environmental noise.<n>Our method provides a rigorous and practical framework for assessing and enhancing the sensor performance in realistic settings.
  arXiv  Detail & Related papers  (2025-04-16T18:06:10Z)
• Experimental distributed quantum sensing in a noisy environment [0.14615254965614236]
  We experimentally demonstrate the associated sensing protocol, using trapped-ion sensors.<n>An entangled state of multi-dimensional sensors is created that isolates and optimally detects a signal.
  arXiv  Detail & Related papers  (2025-01-15T16:42:55Z)
• Fast, accurate, and error-resilient variational quantum noise spectroscopy [0.0]
  We propose a novel approach to overcome limitations of current noise spectroscopies.<n>It self-consistently extracts noise spectra that characterize the interactions between a quantum sensor and its environment.<n>We employ our method to reconstruct the noise spectrum of a nitrogen-vacancy sensor in diamond.
  arXiv  Detail & Related papers  (2024-11-26T03:04:05Z)
• Retrieving space-dependent polarization transformations via near-optimal quantum process tomography [55.41644538483948]
  We investigate the application of genetic and machine learning approaches to tomographic problems. We find that the neural network-based scheme provides a significant speed-up, that may be critical in applications requiring a characterization in real-time. We expect these results to lay the groundwork for the optimization of tomographic approaches in more general quantum processes.
  arXiv  Detail & Related papers  (2022-10-27T11:37:14Z)

This list is automatically generated from the titles and abstracts of the papers in this site.

This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.