Sources on quantum ghost imaging

Quantum ghost imaging is a fascinating area of study within quantum optics, leveraging entangled photons to create images with unique properties. This field has rapidly evolved in recent years, leading to various innovative applications and techniques. Below are some recent and significant sources that can provide deeper insights into current research on quantum ghost imaging as of 2025.

Key Recent Research Sources

1. Quantum Ghost Imaging of Transparent Birefringent Patterns

Researchers have explored quantum ghost imaging techniques applied to transparent birefringent vortex phase patterns. This study discusses how these patterns can enhance imaging capabilities, providing insights into the behavior of light in complex media. The complete research can be found in Scientific Reports Nature (Devrari, 2025).

2. 3D Quantum Ghost Imaging Microscope Development

The Lawrence Livermore National Laboratory has developed a pioneering 3D quantum ghost imaging microscope that allows for detailed imaging at the nanoscale without the need for scanning the object. This innovative approach could significantly enhance imaging in various scientific fields. More details about their findings are available in an article published by Optica LLNL (2025).

3. Scattering-Based 3D Imaging Techniques

A research paper outlines a new method for collecting quantum ghost images orthogonally via scattering. This approach addresses some limitations of conventional imaging techniques by offering a scanning-free method to achieve 3D images. The findings are documented in Optica Optica (Eshun, 2025).

4. Review of Quantum Imaging Methods

A comprehensive review focuses on various quantum imaging methods, detailing dominant technologies and implementations. This source is particularly beneficial for understanding the broader context of quantum imaging techniques, including quantum ghost imaging. You can find the review in Advanced Quantum Technologies ScienceDirect (Ryan, 2025).

5. Ghost Imaging Utilizing Entangled Photons

This research demonstrates the application of ghost imaging principles in the context of Grover's search algorithm, showcasing how photon entanglement can enable efficient imaging techniques. For those interested in the intersection of quantum computing and imaging, this study provides valuable insights. The research is available on Quantum Zeitgeist Quantum Zeitgeist (2025).

6. Single-Pixel Quantum Ghost Imaging

Researchers have presented new patterns generated using the Ising model for single-pixel quantum ghost imaging, illustrating advancements in algorithmic approaches to enhance imaging capability. A detailed account of this study can be explored in Scientific Reports Nature (Oliaei-Moghadam, 2025).

7. Numerical Simulations of Ghost Imaging

A study focusing on the numerical simulation of classical and quantum ghost imaging techniques under atmospheric turbulence provides critical insights into the practical challenges faced in the field. This research can be found in the proceedings of the SPIE conference SPIE (Fasone, 2025).

8. Remote Target Imaging with SPAD Technology

This paper discusses a method for quantum ghost imaging of remote targets using a Single-Photon Avalanche Diode (SPAD), which enhances imaging flexibility and practicality. The findings emphasize advancements in capturing distant objects without prior knowledge of their distance. Access the full study through Optica Optica (Proietti, 2025).

9. Sparse Spatial Mode Reconstruction

The use of sparse spatial mode reconstruction techniques in quantum ghost imaging is explored, with implications for both fundamental research and practical applications. This study appears in Advanced Quantum Technologies Wiley (Nothlawala, 2025).

10. 3D Quantum Ghost Imaging Insights

Another exploration into 3D quantum ghost imaging emphasizes the potential of this technology in various scientific domains, offering insights into advanced imaging techniques that leverage quantum properties. Further details can be accessed via Optica Open Preprints Optica (Eshun, 2025).

Conclusion

Quantum ghost imaging is evolving rapidly, with significant advancements contributing to its applications across diverse scientific fields. The cited studies reflect not just developments in imaging techniques but also the growing intersection of quantum physics with practical technology. For those engaged in research or interested in the latest in quantum optics, these sources serve as a valuable resource for further exploration.