December 23, 2024

Quantum Shadows: Revolutionary Method Reveals Images Hidden in Noise

Credit: SciTechDaily.comInnovative quantum-inspired imaging technique excels in low-light conditions, providing brand-new potential customers in medical imaging and art conservation.Researchers at the University of Warsaws Faculty of Physics with coworkers from Stanford University and Oklahoma State University have presented a quantum-inspired phase imaging approach based on light intensity connection measurements that is robust to phase noise. A random stage hold-up is presented in between the object and reference light beams– this phase delay replicates a disturbance blocking the basic stage imaging methods.”Our technique will widen prospects in phase measurements, consisting of emerging applications such as in infrared and X-ray imaging and quantum and matter-wave interferometry” concludes Dr. Lapkiewicz.Reference: “Noise-resistant stage imaging with intensity connection” by Jerzy Szuniewicz, Stanislaw Kurdzialek, Sanjukta Kundu, Wojciech Zwolinski, Radoslaw Chrapkiewicz, Mayukh Lahiri and Radek Lapkiewicz, 22 September 2023, Science Advances.DOI: 10.1126/ sciadv.adh5396This work was supported by the Foundation for Polish Science under the FIRST TEAM project “Spatiotemporal photon correlation measurements for quantum metrology and super-resolution microscopy” co-financed by the European Union under the European Regional Development Fund (POIR.04.04.00-00-3004/ 17-00).

An innovative stage imaging method, resistant to phase noise and effective in dim light, has actually been established by global scientists. Credit: SciTechDaily.comInnovative quantum-inspired imaging technique excels in low-light conditions, providing new prospects in medical imaging and art conservation.Researchers at the University of Warsaws Faculty of Physics with associates from Stanford University and Oklahoma State University have introduced a quantum-inspired phase imaging technique based on light intensity connection measurements that is robust to phase sound.”It makes it possible for label-free and quantitative characterization of living specimens, such as cell cultures, and can discover applications in neurobiology or cancer research” describes Dr. Radek Lapkiewicz, head of the Quantum Imaging Laboratory at the University of Warsaws Faculty of Physics.Noise-resistant stage imaging with intensity correlation, Credit: Faculty of Physics, University of WarsawChallenges and Innovations in Phase ImagingHowever, there is still space for enhancement. A random stage hold-up is introduced in between the things and referral light beams– this phase delay mimics a disturbance blocking the standard phase imaging techniques.”Our method will expand prospects in stage measurements, consisting of emerging applications such as in infrared and X-ray imaging and quantum and matter-wave interferometry” concludes Dr. Lapkiewicz.Reference: “Noise-resistant phase imaging with intensity correlation” by Jerzy Szuniewicz, Stanislaw Kurdzialek, Sanjukta Kundu, Wojciech Zwolinski, Radoslaw Chrapkiewicz, Mayukh Lahiri and Radek Lapkiewicz, 22 September 2023, Science Advances.DOI: 10.1126/ sciadv.adh5396This work was supported by the Foundation for Polish Science under the FIRST TEAM project “Spatiotemporal photon correlation measurements for quantum metrology and super-resolution microscopy” co-financed by the European Union under the European Regional Development Fund (POIR.04.04.00-00-3004/ 17-00).