Quantum Imaging utilizes the entanglement of photons to achieve enhanced imaging capabilities.

Quantum Imaging finds applications in various fields, including medical imaging, microscopy, astronomy, and remote sensing.

Quantum Imaging offers advantages such as improved resolution, enhanced sensitivity, and reduced noise compared to classical imaging techniques.

Path entanglement is commonly employed in Quantum Imaging due to its ability to enhance imaging resolution and sensitivity.

Quantum states play a crucial role in Quantum Imaging, affecting the properties of entangled photons, influencing the imaging process, and providing information about the imaged object.

Quantum Imaging faces challenges such as scalability, noise and decoherence, and limited availability of entangled photon sources.

Quantum illumination offers advantages such as enhanced signal-to-noise ratio, improved image resolution, and the ability to image in low-light conditions.

Quantum Imaging holds potential for early cancer detection, non-invasive imaging of internal organs, and real-time monitoring of biological processes in medicine.

Quantum sensors play a crucial role in Quantum Imaging by detecting and measuring quantum properties of light, enhancing the sensitivity of imaging systems, and enabling imaging at the nanoscale.

Recent advancements in Quantum Imaging include the development of quantum-enhanced microscopes, demonstration of quantum ghost imaging, and realization of quantum lithography.

Quantum Imaging research aims to develop new imaging techniques with enhanced capabilities, explore the fundamental limits of imaging, and understand the interactions between light and matter at the quantum level.

Quantum Imaging has potential applications in astronomy, including imaging of exoplanets, study of black holes and neutron stars, and observation of distant galaxies.

Quantum Imaging contributes to the field of quantum information science by providing insights into quantum entanglement and quantum states, enabling the development of quantum communication and cryptography protocols, and helping in the realization of quantum computing systems.

The widespread adoption of Quantum Imaging faces challenges such as scalability and cost-effectiveness, development of efficient and reliable quantum light sources, and standardization of quantum imaging techniques.