Comparison of two laser wavelengths for LIBS bioimaging of plants grown in lunar regolith

TL;DR

This study compares two laser wavelengths for LIBS bioimaging of plants grown in lunar regolith, finding the 2090 nm wavelength yields better plasma characteristics and nutrient detection, supporting its use in extraterrestrial plant monitoring.

Contribution

It demonstrates the effectiveness of 2090 nm LIBS for bioimaging plant tissues in lunar regolith, highlighting improved plasma and nutrient detection over the conventional 1064 nm wavelength.

Findings

2090 nm laser produces higher SNR and emissivity than 1064 nm.

Both wavelengths confirmed higher Mg and Ca uptake from lunar regolith.

2090 nm laser supports more efficient plasma ionization for bioimaging.

Abstract

The colonisation of extraterrestrial planets requires sustainable food production independent of Earth-based supplies. Due to the high costs and complicated logistics of food transport, in-situ cultivation will be essential. Growing plants directly in regolith offers a practical approach to achieve sustainable long-term human habitation beyond Earth. In this study, Laser-Induced Breakdown Spectroscopy (LIBS) technique was employed for bioimaging of broccoli (Brassica oleracea) and salad (Lactuca sativa) plants grown in Lunar regolith simulant and control substrate. For this purpose, the potential of the 2090 nm laser wavelength for bioimaging of plant tissue was studied compared to the conventional 1064 nm. The signal-to-noise ratio (SNR), total emissivity ($\epsilon_{\mathrm{tot}}$), and Mg II / Mg I intensity ratio (ionisation degree) were all higher when using the 2090 nm laser wavelength compared to 1064 nm. These findings indicate that the 2090 nm laser produces a hotter and more efficiently ionised plasma, supporting its feasibility for bioimaging of plant tissues. Additionally, bioimaging with both laser wavelengths confirmed higher uptake of key plant nutrients such as magnesium (Mg) and calcium (Ca) from Lunar regolith simulant. These results support the potential of LIBS as a diagnostic tool for plant growth monitoring in extraterrestrial environments.