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Terrestrial laser scanning and low magnetic field digitization yield similar architectural coarse root traits for 32-year-old Pinus ponderosa trees

Authors :
Antonio Montagnoli
Andrew T. Hudak
Pasi Raumonen
Bruno Lasserre
Mattia Terzaghi
Carlos A. Silva
Benjamin C. Bright
Lee A. Vierling
Bruna N. de Vasconcellos
Donato Chiatante
R. Kasten Dumroese
Source :
Plant Methods, Vol 20, Iss 1, Pp 1-13 (2024)
Publication Year :
2024
Publisher :
BMC, 2024.

Abstract

Abstract Background Understanding how trees develop their root systems is crucial for the comprehension of how wildland and urban forest ecosystems plastically respond to disturbances such as harvest, fire, and climate change. The interplay between the endogenously determined root traits and the response to environmental stimuli results in tree adaptations to biotic and abiotic factors, influencing stability, carbon allocation, and nutrient uptake. Combining the three-dimensional structure of the root system, with root morphological trait information promotes a robust understanding of root function and adaptation plasticity. Low Magnetic Field Digitization coupled with AMAPmod (botAnique et Modelisation de l’Architecture des Plantes) software has been the best-performing method for describing root system architecture and providing reliable measurements of coarse root traits, but the pace and scale of data collection remain difficult. Instrumentation and applications related to Terrestrial Laser Scanning (TLS) have advanced appreciably, and when coupled with Quantitative Structure Models (QSM), have shown some potential toward robust measurements of tree root systems. Here we compare, we believe for the first time, these two methodologies by analyzing the root system of 32-year-old Pinus ponderosa trees. Results In general, at the total root system level and by root-order class, both methods yielded comparable values for the root traits volume, length, and number. QSM for each root trait was highly sensitive to the root size (i.e., input parameter PatchDiam) and models were optimized when discrete PatchDiam ranges were specified for each trait. When examining roots in the four cardinal direction sectors, we observed differences between methodologies for length and number depending on root order but not volume. Conclusions We believe that TLS and QSM could facilitate rapid data collection, perhaps in situ, while providing quantitative accuracy, especially at the total root system level. If more detailed measures of root system architecture are desired, a TLS method would benefit from additional scans at differing perspectives, avoiding gravitational displacement to the extent possible, while subsampling roots by hand to calibrate and validate QSM models. Despite some unresolved logistical challenges, our results suggest that future use of TLS may hold promise for quantifying tree root system architecture in a rapid, replicable manner.

Details

Language :
English
ISSN :
17464811
Volume :
20
Issue :
1
Database :
Directory of Open Access Journals
Journal :
Plant Methods
Publication Type :
Academic Journal
Accession number :
edsdoj.494d7651b8464c5eb55b2abdbf9613d5
Document Type :
article
Full Text :
https://doi.org/10.1186/s13007-024-01229-9