Variation of physiological parameters in juvenile treetops of Eucalyptus tereticornis from a three-dimensional perspective

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Publicado: dic 7, 2018
DOI: https://doi.org/10.31876/re.v2i23.399
Palabras clave:
Forest physiology, tree physiology, 3D modeling.

Contenido principal del artículo

Juan Carlos Valverde
Costa Rican Institute of Technology
http://orcid.org/0000-0002-3181-1346
Dagoberto Arias
Rican Institute of Technology.
http://orcid.org/0000-0002-3056-9172

Resumen

We analyzed the characterization of physiological variables in treetops of E. tereticornis; obtaining An of 28.6-40.6 μmol m-2s-1, E of 8.53-16.90 μmol m-2s-1, Gs of 87.47-335.16 mmol m-2s-1, Pp of 65-320 kPa and SPAD of 20.5-38.40; The analysis showed that external and medium branch in higher treetop obtained physiological behaviors significantly lower than the rest of treetop, because they are growing and leaves have not yet reached their peak. Also, we found that 3D model allowed the developed model that simplified information.

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Cómo citar
Valverde, J. C., & Arias, D. (2018). Variation of physiological parameters in juvenile treetops of Eucalyptus tereticornis from a three-dimensional perspective. Espirales Revista Multidisciplinaria De investigación, 2(23). https://doi.org/10.31876/re.v2i23.399
Número
Vol. 2 Núm. 23 (2018): Diciembre
Sección
Artículos
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Biografía del autor/a

Juan Carlos Valverde, Costa Rican Institute of Technology

Forestry engineer and Researcher, specialist in physiology and hydraulics of trees, in development instrumentation and use of biomass for energy purposes. Forest Engineer School.

Dagoberto Arias, Rican Institute of Technology.

Forestry engineer. Professor and researcher in arboreal physiology and production optimization and use of biomass for energy purposes. Forest Engineer School. Costa
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Bussiere, F., Solmon, F., & Fouere, A. (2002). Implementation and evaluation of DROP, a model for the simulation of rainfall distribution below plants described in 3D. Agronomie, 93-103.

Bylesjö, M., Segura, V., Soolanayakanahally, R., Rae, A., Gustafsson, P., Jansson, S., & Street, N. (2008). LAMINA: a tool for rapid quantification of leaf size and shape Parameters. BMC Plant Biology, DOI. 10.1186/1471-2229-8-82.

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de Moraes Frasson, R., & Krajewski, W. (2010). Three-dimensional digital model of a maize plant. Agri For Met, 478–488.

Dornbusch, T., Wernecke, P., & Diepenbrock, W. (2007). A method to extract morphological traits of plant organs from 3D point clouds as a database for an architectural plant model. Ecological Modelling, 119–129.

England, J., & Attiwill, P. (2011). Changes in stomatal frequency, stomatal conductance and cuticle thickness during leaf expansion in the broad-leaved evergreen species, Eucalyptus regnans. Trees, 987–996.

España, M., Baret, F., Aries, F., Chelle, M., Andrieu, B., & Prévot, L. (1999). Modeling maize canopy 3D architecture – application to reflectance simulation. Ecol Mod, 25–43.

Gautier, H., Meïch, R., Prusinkiewicz, H., & Varlet-Grancher, A. (2000). 3D Architectural Modelling of Aerial Photomorphogenesis in White Clover (Trifolium repens L.) using L-systems. Anns Bot, 359-370.

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Kaminuma, E., Heida, N., Tsumoto, Y., Yamamoto, N., Goto, N., & Okamoto, N. (2007). Automatic quantification of morphological traits via three-dimensional measurement of Arabidopsis. Plant J, 358-365.

Lisboa, M., Acuña, E., Cancino, J., Chao, F., Muñoz, F., Rodríguez, R., & Volker, P. (2014). Physiological response to pruning severity in Eucalyptus regnans plantations. New Forest, 753-764.

Medhurst, J., Pinkard, E., Beadle, C., & Worledge, D. (2006). Photosynthetic capacity increases in Acacia melanoxylon following form pruning in a two-species plantation. Forest Ecology and Management, DOI 10.1016/j.foreco.2006.05.016.

Paulus, S. S., Kuhlmann, L., & León, J. (2014). High-precision laser scanning system for capturing 3D plant architecture and analysing growth of cereal plants. Bios y stems engineering , 1-14.

Pinkard, E., & Beadle, C. (1998). Regulation of photosynthesis in Eucalyptus nitens (Deane and Maiden) Maiden following green pruning. Trees, 366-376.

Seelig, H., Hoehn, A., Stodieck, L., Klaus, D., Adams, W., & Emery, J. (2009). Plant water parameters and the remote sensing R1300/R1450 leaf water index: controlled condition dynamics during the development of water deficit stress. Irrig Sci , 357-365.

Shurong, M., Xuifeng, Y., & Yuangang, Z. (1999). Relationship between stomatal behavior and characteristics of photosynthesis and transpiration of Adenophora Iobophyllaand and A. potaninii at different altitudes. Journal of Forest Reseach, 39-41.

Thomas, P. (2000). Trees: Their Natural History. Cambridge: Cambridge University Press .

Utkhao, W., & Yingjajaval, S. (2015). Changes in leaf gas exchange and biomass of Eucalyptus camaldulensis in response to increasing drought stress induced by polyethylene glycol. Trees, 1581–1592.

van Wijk, M., Williams, M., & Shaver, G. (2007). Tight coupling between leaf area index and foliage N content in arctic plant communitie. Oecol , no, 421–427.

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