December 13, 2024 by US Department of Energy

Collected at: https://phys.org/news/2024-12-infrared-quantum-ghost-imaging-illuminates.html

A study published in the journal Optica demonstrates live plant imaging of several representative plant samples, including the biofuel crop sorghum. By employing a novel detector, researchers obtained clear images of living sorghum plants with a light far dimmer than starlight. This advance enables imaging of delicate, light-sensitive samples, such as biofuel crops, without disturbing or damaging the plants.

A method called quantum ghost imaging (QGI) allows scientists to capture images at extremely low light levels. QGI also enables the use of one low intensity color, best matched to the sample and a different color at higher intensity, sufficient to form the image of the sample. This approach improves imaging in regions of light where traditional cameras struggle.

By using label-free infrared imaging, researchers can gather critical information about important plant processes, such as water content and photosynthesis, even in low-light conditions. This is particularly beneficial for studying biofuel crops, where researchers want to optimize plant growth and health to maximize yield and sustainability.

Using NCam, a novel single-photon detector, researchers demonstrated non-degenerate QGI with unprecedented sensitivity and contrast, obtaining images of living plants with less than 1% light transmission. The plants were imaged with a photon flux that is orders of magnitude below starlight. The method used infrared light in the plant to detect chemicals that can only be seen at these wavelengths, and visible light where detectors are better designed.

Non-degenerate QGI probes a sample at one wavelength while forming an image with correlated photons at a different wavelength. This spectral separation alleviates the need for imaging detectors with high sensitivity in the near-infrared region, thereby reducing the required illumination intensity.

QGI offers key advantages for plant research. This ultra-sensitive technique allows for detailed monitoring of plant health and growth without exposing the crops to harmful light levels, which could stress or damage the plants. QGI also removes the need to insert dyes or other “labels” into plants. These labels can help researchers view microscopic features, but they can also interfere with plant processes.

This realization of QGI expands the method to extremely low light bioimaging and imaging of light-sensitive samples, where minimizing illumination intensity is crucial to prevent phototoxicity or sample degradation. This work was performed, in part, at the Center for Integrated Nanotechnologies, a Department of Energy Office of Science user facility.

More information: Duncan P. Ryan et al, Infrared quantum ghost imaging of living and undisturbed plants, Optica (2024). DOI: 10.1364/OPTICA.527982

Journal information: Optica 

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