Temporal Changes of Leaf Spectral Properties and Rapid Chlorophyll-A Fluorescence under Natural Cold Stress in Rice Seedlings

• Published in: Plants (Basel) Vol. 12; no. 13; p. 2415
• Main Authors: Székely, Árpád, Szalóki, Tímea, Jancsó, Mihály, Pauk, János, Lantos, Csaba
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 22.06.2023; MDPI
• Subjects: Absorbance; Aquatic plants; Botanical research; chilling stress; Chlorophyll; Cold; Cold weather; Crop yield; Cultivars; Data acquisition; Environmental aspects; Fluorescence; Genotypes; Leaves; Light; Low temperature; Nitrogen; Optical properties; Parameter identification; photosynthetic quenching analysis; Physiological aspects; Properties; Reflectance; Remote sensing; Rice; Seedlings; spectral indices; Spectrometers; Stress (Physiology); Temperature; Tolerances; Transmittance; Wavelengths; Hungary; absorbance; photosynthetic quenching analysis; reflectance; chilling stress; spectral indices
• ISSN: 2223-7747; 2223-7747
• DOI: 10.3390/plants12132415

Nowadays, hyperspectral remote sensing data are widely used in nutrient management, crop yield forecasting and stress monitoring. These data can be acquired with satellites, drones and handheld spectrometers. In this research, handheld spectrometer data were validated by chlorophyll-a fluorescence measurements under natural cold stress. The performance of 16 rice cultivars with different origins and tolerances was monitored in the seedling stage. The studies were carried out under field conditions across two seasons to simulate different temperature regimes. Twenty-four spectral indices and eleven rapid chlorophyll-a fluorescence parameters were compared with albino plants. We identified which wavelengths are affected by low temperatures. Furthermore, the differences between genotypes were characterized by certain well-known and two newly developed (AAR and RAR) indices based on the spectral difference between the genotype and albino plant. The absorbance, reflectance and transmittance differences from the control are suitable for the discrimination of tolerant-sensitive varieties, especially based on their shape, peak and shifting distance. The following wavelengths are capable of determining the tolerant varieties, namely 548-553 nm, 667-670 nm, 687-688 nm and 800-950 nm in case of absorbance; above 700 nm for reflectance; and the whole spectrum (400-1100 nm) for transmittance.