Search

Your search keyword '"Sathornkich, Jate"' showing total 22 results
Start Over Author "Sathornkich, Jate"
22 results on '"Sathornkich, Jate"'

1. Measuring Photosynthesis of Entire Tree Crowns and Pulse Label Trees in Large Closed Chamber with 13CO2 in the Field: Design and Testing

Author

Duangngam, Ornuma, primary, Sathornkich, Jate, additional, Thaler, Philippe, additional, Chayawat, Chompunut, additional, Phattaralerphong, Jessada, additional, Chantuma, Pisamai, additional, Priault, Pierrick, additional, Desalme, Dorine, additional, Satakhun, Duangrat, additional, Kayankit, Phetrada, additional, Kasemsap, Poonpipope, additional, and Epron, Daniel, additional

Published
2023
Full Text
View/download PDF

2. Measuring photosynthesis of entire tree crowns and pulse label trees in large closed chamber with 13co2 in the field: Design and testing

Author

Duangngam, Onouma, Sathornkich, Jate, Thaler, Philippe, Chayawat, Chompunut, Phattaralerphong, Jessada, Chantuma, Pisamai, Priault, Pierrick, Desalme, Dorine, Satakhun, Duangrat, Kayankit, Phetrada, Kasemsap, Poonpipope, Epron, Daniel, Duangngam, Onouma, Sathornkich, Jate, Thaler, Philippe, Chayawat, Chompunut, Phattaralerphong, Jessada, Chantuma, Pisamai, Priault, Pierrick, Desalme, Dorine, Satakhun, Duangrat, Kayankit, Phetrada, Kasemsap, Poonpipope, and Epron, Daniel

Abstract

Measuring the photosynthesis of entire tree crowns and pulse labelling trees with 13CO2 are valuable approaches to study carbon acquisition, transfer, and allocation; however, it is challenging for trees in the field. The objective was to develop and field test large chambers (35 - 45 m3) that enclosed the entire crown of a tree, provided a reliable estimate of tree crown photosynthesis, and ensured efficient 13CO2 labelling. The chambers, made of transparent polyethylene film pulled tightly over a frame, were equipped with an air conditioner, fans, and air blowers. Air temperature, relative humidity, and photosynthetic photon flux density were measured outside and inside each chamber. Six of 4-year-old rubber trees (Hevea brasiliensis) were pulsed-labelled with 18 L of 13CO2 in June and October 2016. The mean air temperature inside the chambers was 1.2 °C higher and the relative humidity 8 % lower than the outside air. The crown photosynthesis, calculated from the decrease in the CO2 concentration inside the chamber, was in the range 140 - 249 µmol s–1 and was significantly related to photosynthetic photon flux density, total leaf area of the tree, and average net CO2 assimilation at leaf level. The labelling efficiency, estimated as the ratio of the amount of 13C recovered in the foliage immediately after labelling divided by the amount of 13C delivered to the tree, was in the range 43 - 68 %. The designed chamber was suitable to estimate crown photosynthesis and perform 13CO2 pulse labelling of 5-m-tall trees in the field.

Published
2023

3. Measuring Photosynthesis of Entire Tree Crowns and Pulse Label Trees in Large Closed-Chamber with 13CO2 in the Field: Design and Testing.

Author

Duangngam, Ornuma, Sathornkich, Jate, Thaler, Philippe, Chayawat, Chompunut, Phattaralerphong, Jessada, Chantuma, Pisamai, Priault, Pierrick, Desalme, Dorine, Satakhun, Duangrat, Kayankit, Phetrada, Kasemsap, Poonpipope, and Epron, Daniel

Subjects
*CROWNS (Botany), *PHOTOSYNTHESIS, *HEVEA, *POLYETHYLENE films, *ACTINIC flux
Abstract

Measuring the photosynthesis of entire tree crowns and pulse labelling trees with 13CO2 are valuable approaches to study carbon acquisition, transfer, and allocation; however, it is challenging for trees in the field. The objective was to develop and field test large chambers (35 - 45 m3) that enclosed the entire crown of a tree, provided a reliable estimate of tree crown photosynthesis, and ensured efficient 13CO2 labelling. The chambers, made of transparent polyethylene film pulled tightly over a frame, were equipped with an air conditioner, fans, and air blowers. Air temperature, relative humidity, and photosynthetic photon flux density were measured outside and inside each chamber. Six of 4-year-old rubber trees (Hevea brasiliensis) were pulsed-labelled with 18 L of 13CO2 in June and October 2016. The mean air temperature inside the chambers was 1.2 °C higher and the relative humidity 8 % lower than the outside air. The crown photosynthesis, calculated from the decrease in the CO2 concentration inside the chamber, was in the range 140 - 249 µmol s-1 and was significantly related to photosynthetic photon flux density, total leaf area of the tree, and average net CO2 assimilation at leaf level. The labelling efficiency, estimated as the ratio of the amount of 13C recovered in the foliage immediately after labelling divided by the amount of 13C delivered to the tree, was in the range 43 - 68 %. The designed chamber was suitable to estimate crown photosynthesis and perform 13CO2 pulse labelling of 5-m-tall trees in the field. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

4. Species-specific and generic biomass equations for seedlings and saplings of European tree species

Author

Annighöfer, Peter, Ameztegui, Aitor, Ammer, Christian, Balandier, Philippe, Bartsch, Norbert, Bolte, Andreas, Coll, Lluís, Collet, Catherine, Ewald, Jörg, Frischbier, Nico, Gebereyesus, Tsegay, Haase, Josephine, Hamm, Tobias, Hirschfelder, Bastian, Huth, Franka, Kändler, Gerald, Kahl, Anja, Kawaletz, Heike, Kuehne, Christian, Lacointe, André, Lin, Na, Löf, Magnus, Malagoli, Philippe, Marquier, André, Müller, Sandra, Promberger, Susanne, Provendier, Damien, Röhle, Heinz, Sathornkich, Jate, Schall, Peter, Scherer-Lorenzen, Michael, Schröder, Jens, Seele, Carolin, Weidig, Johannes, Wirth, Christian, Wolf, Heino, Wollmerstädt, Jörg, and Mund, Martina

Published
2016
Full Text
View/download PDF

6. Carbon and Water Cycling in Two Rubber Plantations and a Natural Forest in Mainland Southeast Asia

Author

Wang, Xueqian, primary, Blanken, Peter D., additional, Kasemsap, Poonpipope, additional, Petchprayoon, Pakorn, additional, Thaler, Philippe, additional, Nouvellon, Yann, additional, Gay, Frédéric, additional, Chidthaisong, Amnat, additional, Sanwangsri, Montri, additional, Chayawat, Chompunut, additional, Chantuma, Pisamai, additional, Sathornkich, Jate, additional, Kaewthongrach, Rungnapa, additional, Satakhun, Duangrat, additional, and Phattaralerphong, Jessada, additional

Published
2022
Full Text
View/download PDF

7. Effects of large scale tree plantations on local climate: what potential for rubber tree plantations?

Author

Nouvellon, Yann, Thaler, Philippe, Gay, Frédéric, Gohet, Eric, Kasemsap, Poonpipope, Chayawat, Chompunut, Le Maire, Guerric, Guillemot, Joannès, Satakhun, Duangrat, Chantuma, Pisamai, Sathornkich, Jate, Stape, Jose Luiz, Campoe, Otavio, Lacote, E., Laclau, Jean-Paul, Nouvellon, Yann, Thaler, Philippe, Gay, Frédéric, Gohet, Eric, Kasemsap, Poonpipope, Chayawat, Chompunut, Le Maire, Guerric, Guillemot, Joannès, Satakhun, Duangrat, Chantuma, Pisamai, Sathornkich, Jate, Stape, Jose Luiz, Campoe, Otavio, Lacote, E., and Laclau, Jean-Paul

Published
2021

9. Contribution of the carbon sources involved in latex regeneration in rubber trees (Hevea brasiliensis): an in situ 13CO2 labelling experiment

Author

Desalme, Dorine, primary, Duangngam, Ornuma, additional, Thaler, Philippe, additional, Kasemsap, Poonpipope, additional, Sathornkich, Jate, additional, Satakhun, Duangrat, additional, Chayawat, Chompunut, additional, Angeli, Nicolas, additional, Chantuma, Pisamai, additional, and Epron, Daniel, additional

Published
2020
Full Text
View/download PDF

10. Tracking carbon from photosynthesis to latex with 13C field labelling experiment

Author

Thaler, Philippe, Desalme, Dorine, Duangngam, Ornuma, Kasemsap, Poonpipope, Sathornkich, Jate, Chayawat, Chompunut, Satakhun, Duangrat, Priault, Pierrick, Angeli, Nicolas, Chantuma, Pisamai, Epron, Daniel, SILVA (SILVA), and Institut National de la Recherche Agronomique (INRA)-Université de Lorraine (UL)-AgroParisTech

Subjects
[SDV.BV]Life Sciences [q-bio]/Vegetal Biology, ComputingMilieux_MISCELLANEOUS
Abstract

The carbon (C) content of dry latex is about 80%. Then, the rubber trees must mobilize huge amount of C to regenerate the latex exported at each tapping. Does the latex C come directly from the primary sources, the leaves where C is assimilated through photosynthesis, or from reserve pools as wood starch, or both? Knowing the actual C sources and knowing the pathways towards latex is necessary to manage the tapping systems. Stable isotopes and especially 13C are widely used in plant science as tracers. We realized a field labeling of full crowns of 3y-old tapped rubber trees with 13CO2 to trace the carbon from its assimilation in the leaves to the tree sinks and particularly to latex. Such experiment has never been done so far on rubber trees. Three trees (RRIT 408) were labelled in June and three other in October, using a specifically designed chamber. We sampled leaves, phloem, wood and latex to analyze their 13C content and determine the dynamics of carbon allocation from leaves to latex. Latex is being sampled during one year. The first results showed that 13C was recovered later in latex than in phloem, indicating that most the latex C does not come directly from recent assimilation. The dynamics showing a peak of 13C in latex 10-15 days after labelling in June are consistent with the hypothesis that newly assimilated C is mixed in a pool of older carbon (reserves) before being used to regenerate latex. However, the dynamics in October showed an earlier (6-8 days after labelling) and much higher peak. This showed that when the regeneration metabolism was well established the transfer of recent assimilates into latex was faster. In both cases 13C was still recovered in significant amount more than 40 days after labelling, demonstrating the contribution of reserves. The dynamics of 13C recovery in soluble compounds (sugars and quebrachitol) in the phloem and in the latex C-serum will provide further information on their transport and use in laticifer cells. The first trends indicated that the mean residence time (MRT) of soluble sugars did not vary (36-45 h in June and October), whereas the dynamics of quebrachitol were different, indicating possible different sources of C for this compound believed to play a key role in osmotic regulation.

Published
2019

12. In situ13CO2 labelling of rubber trees reveals a seasonal shift in the contribution of the carbon sources involved in latex regeneration.

Author

Duangngam, Ornuma, Desalme, Dorine, Thaler, Philippe, Kasemsap, Poonpipope, Sathornkich, Jate, Satakhun, Duangrat, Chayawat, Chompunut, Angeli, Nicolas, Chantuma, Pisamai, and Epron, Daniel

Subjects
LATEX, RUBBER, HEVEA, LABELS, TREES, PHOTOSYNTHATES
Abstract

Rubber trees (Hevea brasiliensis) are the main source of natural rubber, extracted from latex, which exudes from the trunk after tapping. Tapped trees require large amounts of carbon (C) to regenerate the latex after its collection. Knowing the contribution of C sources involved in latex biosynthesis will help in understanding how rubber trees face this additional C demand. Whole crown 13CO2 pulse labelling was performed on 4-year-old rubber trees in June, when latex production was low, and in October, when it was high. 13C content was quantified in the foliage, phloem sap, wood, and latex. In both labelling periods, 13C was recovered in latex just after labelling, indicating that part of the carbohydrate was directly allocated to latex. However, significant amounts of 13C were still recovered in latex after 100 d and the peak was reached significantly later than in phloem sap, demonstrating the contribution of a reserve pool as a source of latex C. The contribution of new photosynthates to latex regeneration was faster and higher when latex metabolism was well established, in October, than in June. An improved understanding of C dynamics and the source–sink relationship in rubber tree is crucial to adapt tapping system practices and ensure sustainable latex production. [ABSTRACT FROM AUTHOR]

Published
2020
Full Text
View/download PDF

13. Tracking carbon from photosynthesis to latex with 13C field labelling experiment

Author

Thaler, Philippe, Desalme, Dorine, Duangngam, Onouma, Kasemsap, Poonpipope, Sathornkich, Jate, Chayawat, Chompunut, Satakhun, Duangrat, Priault, Pierrick, Angeli, Nicolas, Chantuma, Pisamai, Epron, Daniel, Thaler, Philippe, Desalme, Dorine, Duangngam, Onouma, Kasemsap, Poonpipope, Sathornkich, Jate, Chayawat, Chompunut, Satakhun, Duangrat, Priault, Pierrick, Angeli, Nicolas, Chantuma, Pisamai, and Epron, Daniel

Abstract

The carbon (C) content of dry latex is about 80%. Then, the rubber trees must mobilize huge amount of C to regenerate the latex exported at each tapping. Does the latex C come directly from the primary sources, the leaves where C is assimilated through photosynthesis, or from reserve pools as wood starch, or both? Knowing the actual C sources and knowing the pathways towards latex is necessary to manage the tapping systems. Stable isotopes and especially 13C are widely used in plant science as tracers. We realized a field labeling of full crowns of 3y-old tapped rubber trees with 13CO2 to trace the carbon from its assimilation in the leaves to the tree sinks and particularly to latex. Such experiment has never been done so far on rubber trees. Three trees (RRIT 408) were labelled in June and three other in October, using a specifically designed chamber. We sampled leaves, phloem, wood and latex to analyze their 13C content and determine the dynamics of carbon allocation from leaves to latex. Latex is being sampled during one year. The first results showed that 13C was recovered later in latex than in phloem, indicating that most the latex C does not come directly from recent assimilation. The dynamics showing a peak of 13C in latex 10-15 days after labelling in June are consistent with the hypothesis that newly assimilated C is mixed in a pool of older carbon (reserves) before being used to regenerate latex. However, the dynamics in October showed an earlier (6-8 days after labelling) and much higher peak. This showed that when the regeneration metabolism was well established the transfer of recent assimilates into latex was faster. In both cases 13C was still recovered in significant amount more than 40 days after labelling, demonstrating the contribution of reserves. The dynamics of 13C recovery in soluble compounds (sugars and quebrachitol) in the phloem and in the latex C-serum will provide further information on their transport and use in laticifer cells. The f

Published
2017

14. Investigations sur la stratégie de survie des jeunes hêtres (Fagus sylvatica L.) sous faibles conditions de lumière avec une approche de modélisation intégrative

Author

Lacointe, André, Sathornkich, Jate, Marquier, André, NGAO, Jérome, Balandier, Philippe, Institut National de la Recherche Agronomique (INRA), KASETSART UNIVERSITY DEPARTMENT OF HORTICULTURE BANGKOK THA, Partenaires IRSTEA, Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), Ecosystèmes forestiers (UR EFNO), Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), Laboratoire de Physique et Physiologie Intégratives de l’Arbre en environnement Fluctuant - Clermont Auvergne (PIAF), Institut National de la Recherche Agronomique (INRA)-Université Clermont Auvergne (UCA), Kasetsart University, Laboratoire de Physique et Physiologie Intégratives de l’Arbre en environnement Fluctuant (PIAF), Université Clermont Auvergne [2017-2020] (UCA [2017-2020])-Institut National de la Recherche Agronomique (INRA), FSPM., Laboratoire de Physique et Physiologie Intégratives de l'Arbre Fruitier et Forestier (PIAF), Institut National de la Recherche Agronomique (INRA)-Université Blaise Pascal - Clermont-Ferrand 2 (UBP), and Kasetsart University (KU)

Subjects
RESERVE, REGENERATION, HETRE, european beech, [SDE]Environmental Sciences, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, fagus sylvatica, shelterwood felling, regénération, hêtre
Abstract

International audience; Beech (Fagus sylvatica L.) is a shade tolerant species of broadleaved temperate forests from the northern hemisphere. However, how it manages to survive low irradiance conditions is debated. This must involve both carbon balance components (mainly photosynthesis vs. respiration) and efficient utilization / partitioning of the available C resource among the different sinks (mainly growth vs. reserve storage). This survival strategy was investigated through a combined experimental and modelling approach. Four-year-old beech seedlings growing in the understorey of natural Scots pine stands were 3D-digitized in summer for architecture, including woody parts (growth units) and leaves. Then seedlings were harvested in autumn and winter to quantify biomass and carbohydrate reserve contents of each organ, both above and below ground. Roots were separated into 3 classes: taproot, main lateral roots and fine roots, and shoot segments according to their age. These data were used to construct 3D-digital mockups of the young trees and to parameterize and initialize the carbon-based functional-structural model PIAF-1. Additional beech-specific parameters relevant to phenology and gas exchange rates were derived from similar experiments or literature. Meteorological data (daily radiation and temperature) were generated for each tree based on recorded weather data. Transmitted solar irradiance above each seedling was calculated from hemispherical photographs and the global radiation above the stand. The first results suggest that under the most restrictive light conditions, the reserve store was just sufficient for the spring outgrowth. The major factor allowing the seedling to pass the short but critical near-zero-reserve phase appeared to be the leaf growth strategy, with surface area expanding prior to structural hardening. The reserve mobilization strategy showed only as a second factor, with the mobilization rate likely not limiting in contrast to the total reserve store.

Published
2016

15. Investigations sur le rôle de la mobilisation des réserves et le partage des assimilats chez le jeune hêtre à l'ombre à l'aide d'une approche de modélisation intégrée

Author

LACOINTE, André, Sathornkich, Jate, Balandier, Philippe, Laboratoire de Physique et Physiologie Intégratives de l'Arbre Fruitier et Forestier (PIAF), Institut National de la Recherche Agronomique (INRA)-Université Blaise Pascal - Clermont-Ferrand 2 (UBP), Kasetsart University (KU), Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), FSPM., Institut National de la Recherche Agronomique (INRA), KASETSART UNIVERSITY DEPARTMENT OF HORTICULTURE BANGKOK THA, Partenaires IRSTEA, Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), and Ecosystèmes forestiers (UR EFNO)

Subjects
RESERVE, REGENERATION, HETRE, [SDE]Environmental Sciences, CROISSANCE, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, ComputingMilieux_MISCELLANEOUS
Abstract

International audience; Beech (Fagus sylvatica L.) is a species of temperate broadleaved forests known to be very shade-tolerant. How does it manage to sustainably cope with very limited light resource? Processes must involve both C balance components (mainly photosynthesis vs. respiration) and efficient utilization/partitioning of the available C resource among the different sinks (mainly growth vs. reserve storage). We investigated them by combined experimental and integrated modelling approach.

Published
2016

16. Environmental controls on net CO2 exchange over a young rubber plantation in Northeastern Thailand.

Author

Chayawat, Chompunut, Satakhun, Duangrat, Kasemsap, Poonpipope, Sathornkich, Jate, and Phattaralerphong, Jessada

Subjects
RUBBER plantations, RESPIRATION in plants, ATMOSPHERIC carbon dioxide, CARBON cycle, GROWING season, SOLAR radiation, ATMOSPHERIC temperature
Abstract

Net ecosystem CO2 exchange (NEE) over a 5-year-old rubber plantation was measured, using Eddy Covariance technique in 2014 to (1) quantify the seasonal distribution of NEE and its partitioning into daily gross primary production (GPP) and ecosystem respiration (Rd) and (2) examine how key environmental factors influence those carbon fluxes. We found that the daily amplitude of carbon fluxes varied substantially within the growing season, with the largest daily changes occurring in July. The daily maximum NEE generally occurred before noon, while maximum Rd occurred around sunset. The NEE peak of each growth stage was different. The seasonal variations of NEE, GPP and Rd, all of which were closely related to the rubber phenology, reached the peak value in July. Annual NEE, Reco and GPP were 715.21, 591.98, and 1298.93 g C m-2 y-1, respectively. The 5-year-old rubber plantation behaved as a carbon sink from the end of refoliation stage to the beginning of defoliation period, while it acted as a carbon source within 1-2 weeks. The response of daytime NEE to light (PAR, photosynthetic active radiation) showed that 37-69% of the variation in NEE was explained by the change in net solar radiation. The effect of PAR was dependent on growth stage of rubber plantation. The 3-light response parameters, maximum photosynthetic capacity (Pmax), ecosystem apparent quantum yield (α) and ecosystem respiration (Rd), varied with the growth stage, i.e., initial stage, refoliation, fully expanded leaf and defoliation. Range of Pmax, α, and Rd were -9.44 to -46.61 µmol CO2 m-2 s-1, -0.0041 to -0.0428 µmol CO2 µmol-1 photon, and 1.06-4.91 µmol CO2 m-2 s-1, respectively. The highest values of Pmax occurred in defoliation stage. Both of α and Rd were highest in fully expanded leaf stage. The impact of air temperature (Ta) and vapour pressure deficit (VPD) on NEE light response was studied. The magnitude of Pmax, α, and Rd decreased with increasing of Ta. Pmax increased with the increase in VPD, the maximum value of Pmax occurred at low level of VPD (VPD ≼ 1 kPa). Values of and Rd at medium level of VPD (1 < VPD < 2) were the highest. Multiple linear regression and correlation methods were used to assess the relationship between NEE and environmental factors. The environmental factors controlling NEE were different depending on growth stage. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

17. The source of latex. Tracing carbon from leaf photosynthesis to latex metabolism in rubber trees using carbon stable isotopes

Author

Thaler, Philippe, Duangngam, Onouma, Kasemsap, Poonpipope, Sathornkich, Jate, Chayawat, Chompunut, Satakhum, Duangrat, Priault, Pierrick, Desalme, Dorine, Chantuma, Pisamai, Ghashghaie, Jaleh, Epron, Daniel, Thaler, Philippe, Duangngam, Onouma, Kasemsap, Poonpipope, Sathornkich, Jate, Chayawat, Chompunut, Satakhum, Duangrat, Priault, Pierrick, Desalme, Dorine, Chantuma, Pisamai, Ghashghaie, Jaleh, and Epron, Daniel

Abstract

One of the main challenges for the future of Natural Rubber production is the scarcity of skilled manpower to tap the trees. The only way to cope with such issue is to reduce the tapping frequency. The key is the carbon supply to the latex producing tissues. With low tapping frequencies, the latex exported at each tapping day is higher than in traditional systems. Then the trees must mobilize huge amount of carbon at each tapping. Does the latex carbon come directly from the primary sources, the leaves where C is assimilated through photosynthesis, or from reserve pools as wood starch, or both? Knowing the actual C sources and knowing the pathways towards latex is then necessary to manage the tapping systems. Stable isotopes and especially 13C are widely used in plant science as tracers but studying their natural abundance also provides insightful information on tree physiology. We first compared the seasonal variations in natural abundance in tapped and untapped latex of RRIM600 trees to the variations in their leaves which vary according to climate and phenology. We showed that latex δ13C was higher and varied much less than that of leaves in tapped trees. The lack of correlation between variations in δ13C in leaves and in latex suggests that recent photosynthates are mixed in a large pool of stored carbohydrates that are involved in latex regeneration after tapping. We then did a field labeling of full crowns of 3y-old tapped rubber trees with 13CO2 to trace the carbon from its assimilation in the leaves to the tree sinks and particularly to latex. Such experiment, using a specifically designed chamber, has never been done on rubber trees. Three trees (RRIT 408) were labelled in June and three other in October. We sampled leaves, phloem, wood and latex to analyze their 13C content and determine the dynamics of carbon allocation from leaves to reserves and latex. The latex samples will be followed during one year. The presentation describes the methodology and pre

Published
2016

18. Simulation de la croissance et du développement de jeune hêtre poussant sous différents environnements lumineux à l'aide de PIAF-1

Author

Sathornkich, Jate, Lacointe, André, Donès, Nicolas, Balandier, Philippe, Laboratoire de Physique et Physiologie Intégratives de l'Arbre Fruitier et Forestier (PIAF), Institut National de la Recherche Agronomique (INRA)-Université Blaise Pascal - Clermont-Ferrand 2 (UBP), Department of Horticulture, Kasetsart University, Centre national du machinisme agricole, du génie rural, des eaux et forêts (CEMAGREF), KASETSART UNIVERSITY DEPARTMENT OF HORTICULTURE BANGKOK THA, Partenaires IRSTEA, Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA), Institut National de la Recherche Agronomique (INRA), and Écosystèmes forestiers (UR EFNO)

Subjects
Vegetal Biology, HETRE, Fagus silvatica L, MODELE STRUCTURE FONCTION, fagus sylvatica, simulation sofware, 3D digitizing, ARBRE, REGENERATION, [SDE]Environmental Sciences, [SDV.BV]Life Sciences [q-bio]/Vegetal Biology, beech, functional-structural model, Biologie végétale, carbon-based model
Abstract

International audience; The European beech (Fagus silvatica L.) is a late-successional shade tolerant species. It is often cultivated and managed with the shelterwood system in Europe, meaning that its natural regeneration takes place in shade. Under low light conditions, seedling size must stay below a threshold where carbon gain and carbon balance remain positive. This is not so easy to determine experimentally. Therefore, a simulation approach using the carbon-based functional-structural model PIAF-1 (Lacointe and Donès, 2007) was used to investigate the relationship between carbon balance and growth of young beech trees under low light availability. Two-year-old beech seedlings were planted in March 2007 in the understorey of natural Scots pine stands in Fontfreyde, Chaîne des puys, France. In summer 2009, nine beech seedlings were sampled under light availability ranging from 7 to 28% of incident light. To acquire their architecture, aboveground parts of each tree were 3D-digitized, including woody parts (growth units) and leaves using PiafDigit (Donès et al., 2006). Then seedlings were harvested in autumn and winter to quantify biomass and starch and sucrose contents of each organ, above and below ground. Roots were separated into 3 classes: taproot, main lateral roots and fine roots. Each part was scanned and the length and diameter of roots were assessed using WinRhizo (Regent Instruments Inc., Canada). These data were used to parameterize and initialize PIAF-1. The digitized aboveground parts were converted from growth units to cylindrical segments bearing leaves in their true place and orientation. Belowground parts were reconstructed based on diameter and length of each root class. Meteorological data (hourly light and temperature) were generated for each tree based on recorded weather data. Transmitted solar irradiance above each seedling was calculated from hemispherical photographs and the global radiation above the stand. Each seedling was visualized on a PIAF-1 3D visualization interface. The quality of the reconstructed seedlings was assessed by comparing the graphical outputs from PIAF-1 with those from VegeSTAR (Adam et al., 2002) using Tree Analyser (Phattaralerphong et al., 2005) to compute synthetic geometrical properties such as total leaf area or density. Potential growth, amount of storage, and reserve capacity of stem, leaf and root are still being analyzed. Results of simulations will be reported and discussed.

Published
2010

19. A photographic gap fraction method for estimating leaf area of isolated trees: assessment with 3D digitized plants

Author

Phattaralerphong, Jessada, Sathornkich, Jate, Sinoquet, Hervé, Laboratoire de Physique et Physiologie Intégratives de l'Arbre Fruitier et Forestier (PIAF), Institut National de la Recherche Agronomique (INRA)-Université Blaise Pascal - Clermont-Ferrand 2 (UBP), Faculty of Science, Department of Botany, Kasetsart University, Faculty of Agriculture, Department of Agronomy, ProdInra, Archive Ouverte, and Kasetsart University (KU)

Subjects
IMAGE PROCESSING, MODELISATION TRIDIMENSIONNELLE, [SDV.SA.SF]Life Sciences [q-bio]/Agricultural sciences/Silviculture, forestry, TRAITEMENT D'IMAGE, PERSPECTIVE IMAGE, [SDV.SA.SF] Life Sciences [q-bio]/Agricultural sciences/Silviculture, forestry, TREE ANALYSER
Abstract

A method for computing leaf area of isolated trees from perspective photographs was developed. The method is based on gap fraction inversion. Photographs are discretized into picture zones where gap fraction is computed from image processing. Canopy volume and leaf area density associated with each picture zone are computed from geometrical considerations and inversion of gap fraction equations. Total leaf area and the vertical profile of leaf area are computed from the product of associated volume and its density. The method has been implemented in software called Tree Analyser, written in C++. The method has been tested by comparison with direct estimation of leaf area of three-dimensional (3D) digitized trees of walnut, peach, mango, olive and rubber. Estimated leaf area was sensitive to picture discretization, individual leaf size and leaf inclination distribution. Optimal size of picture discretization was 17 times projected leaf size. Total leaf area was estimated by using a set of eight photographs taken around the tree in the main horizontal directions: deviation ranged from -11% in peach tree to +5% in rubber tree. The method allows fast and nondestructive monitoring of leaf area of individual tree canopies. The next version of the method will include the estimation of 3D leaf area distribution within the canopy.

Published
2006

Catalog

Books, media, physical & digital resources
See catalog results