Size‐mediated ageing reduces vigour in trees

Mencuccini, Maurizio; Martínez‐Vilalta, Jordi; Vanderklein, Dirk; Hamid, Hasmiandy; Korakaki, Evangelia; Lee, S.; Michiels, Boudewijn

doi:10.1111/j.1461-0248.2005.00819.x

Cited by 333 publications

(293 citation statements)

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“…Finalmente, dado que el tamaño de los árboles puede condicionar la predisposición al decaimiento, la variable diámetro a la altura del pecho (dap) también fue considerada en los análisis (Mencuccini et al, 2005;Bigler, 2016).…”

Section: Introductionunclassified

Indicadores del decaimiento en bosques de Nothofagus pumilio en el norte de la Patagonia, Argentina

Rodríguez‐Catón

Villalba

2018

MYB

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El decaimiento forestal está frecuentemente asociado a la mortalidad parcial o total de las copas en un alto porcentaje de individuos de un rodal. Si bien el decaimiento ha sido documentado a escala global, las relaciones entre las condiciones externas de los árboles y su crecimiento radial raramente han sido exploradas. El presente trabajo relaciona la intensidad del decaimiento con el crecimiento radial en 294 árboles de Nothofagus pumilio en el norte de la Patagonia. Los indicadores externos del decaimiento analizados fueron la mortalidad de la copa, la sanidad de la corteza, la incidencia de insectos barrenadores y pájaros carpinteros, así como la presencia de plantas hemiparásitas, hongos y líquenes. Los resultados indican que elevados porcentajes de mortalidad de copa están significativamente relacionados con la disminución del crecimiento radial promedio, siendo esta relación más notoria cuando se usa como medida del crecimiento radial el incremento en área basal en lugar del ancho de los anillos. El deterioro de la corteza y la abundancia de cavidades producto de las actividades de insectos barrenadores y de pájaros carpinteros también estuvieron significativa e inversamente relacionados con el crecimiento. Por el contrario, el crecimiento y la presencia de hemiparásitas, hongos o líquenes no mostraron relaciones significativas. A partir de estos resultados, se propone utilizar en la estimación de la sanidad forestal los indicadores externos (1) mortalidad de copa, (2) deterioro de la corteza y (3) cavidades de insectos y/o pájaros carpinteros, como una medida integral del decaimiento forestal de Nothofagus pumilio en la Patagonia.

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Section: Introductionunclassified

Indicadores del decaimiento en bosques de Nothofagus pumilio en el norte de la Patagonia, Argentina

Rodríguez‐Catón

Villalba

2018

MYB

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“…Gas exchange characteristics may change as trees become larger due to sizedependent variation in environmental and structural factors and their interactions, such as changes in light availability, hydraulic conductance, and carbon allocation (e.g., Yoder et al 1994;Gower et al 1996;Ryan and Yoder 1997). Some traits, such as leaf mass per area and sexual maturation, vary with meristem age independently of size (Bond 2000;Bond et al 2007;Greenwood et al 2008;Thomas 2011); however, developmental changes in gas exchange are driven by tree size rather than age (Day et al 2002;Mencuccini et al 2005;Bond et al 2007;Steppe et al 2011). Thus, we use the term size rather than age throughout this paper (McDowell et al 2005).…”

Section: Introductionmentioning

confidence: 99%

Relationships Between Tree Height and Carbon Isotope Discrimination

et al. 2011

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Understanding how tree size impacts leaf-and crown-level gas exchange is essential to predicting forest yields and carbon and water budgets. The stable carbon isotope ratio (d 13 C) of organic matter has been used to examine the relationship of gas exchange to tree size for a host of species because it carries a temporally integrated signature of foliar photosynthesis and stomatal conductance. The carbon isotope composition of leaves reflects discrimination against 13 C relative to 12 C during photosynthesis and is the net result of the balance of change in CO 2 supply and demand at the sites of photosynthesis within the leaf mesophyll. Interpreting the patterns of changes in d 13 C with tree size are not always clear, however, because multiple factors that regulate gas exchange and carbon isotope discrimination (D) co-vary with height, such as solar irradiance and hydraulic conductance. Here we review 36 carbon isotope datasets from 38 tree species and conclude that there is a consistent, linear decline of D with height. The most parsimonious explanation of this result is that gravitational constraints on maximum leaf water potential set an ultimate boundary on the shape and sign of the relationship. These hydraulic constraints are manifest both over the long term through impacts on leaf structure, and over diel periods via impacts on stomatal conductance, photosynthesis and leaf hydraulic conductance. Shading induces a positive offset to the linear decline, consistent with light limitations reducing carbon fixation and increasing partial pressures of CO 2 inside of the leaf, p c at a given height. Biome differences between tropical and temperate forests were more important in predicting D and its relationship to height than wood type associated with being an angiosperm or gymnosperm. It is not yet clear how leaf internal conductance varies with leaf mass area, but some data in particularly tall, temperate conifers suggest that photosynthetic capacity may not vary dramatically with height when compared between tree-tops, while stomatal and leaf internal conductances do decline in unison with height within canopy gradients. It is also clear that light is a critical variable low in the canopy, whereas hydrostatic constraints dominate the relationship between D and height in the upper canopy. The trend of increasing maximum height with decreasing minimum D suggests that trees that become particularly tall may be adapted to tolerate particularly low values of p c .

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“…Thus, large, old trees do not act simply as senescent carbon reservoirs but actively fix large amounts of carbon compared to smaller trees; at the extreme, a single big tree can add the same amount of carbon to the forest within a year as is contained in an entire mid-sized tree. The apparent paradoxes of individual tree growth increasing with tree size despite declining leaf-level [8][9][10] and stand-level 10 productivity can be explained, respectively, by increases in a tree's total leaf area that outpace declines in productivity per unit of leaf area and, among other factors, age-related reductions in population density. Our results resolve conflicting assumptions about the nature of tree growth, inform efforts to undertand and model forest carbon dynamics, and have additional implications for theories of resource allocation 11 and plant senescence 12 .…”

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confidence: 99%

“…Although the results of a few single-species studies have been consistent with this assumption 15 , the bulk of evidence cited in support of declining growth is not based on measurements of individual tree mass growth. Instead, much of the cited evidence documents either the well-known age-related decline in net primary productivity (hereafter 'productivity') of even-aged forest stands 10 (in which the trees are all of a similar age) or size-related declines in the rate of mass gain per unit leaf area (or unit leaf mass) [8][9][10] , with the implicit assumption that declines at these scales must also apply at the scale of the individual tree. Declining tree growth is also sometimes inferred from life-history theory to be a necessary corollary of increasing resource allocation to reproduction 11,16 .…”

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confidence: 99%

“…First, although growth efficiency (tree mass growth per unit leaf area or leaf mass) often declines with increasing tree size [8][9][10] , empirical observations and metabolic scaling theory both indicate that, on average, total tree leaf mass increases as the square of trunk diameter 17,18 . A typical tree that experiences a tenfold increase in diameter will therefore undergo a roughly 100-fold increase in total leaf mass and a 50-100-fold Table 1.…”

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Rate of tree carbon accumulation increases continuously with tree size

Stephenson

Das

Condit

et al. 2014

Nature

741

486

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After more than a century of research the typical growth pattern of a tree was thought to be fairly well understood. Following germination height growth accelerates for some time, then increment peaks and the added height each year becomes less and less. The cross sectional area (basal area) of the tree follows a similar pattern, but the maximum basal area increment occurs at some time after the maximum height increment. An increase in basal area in a tall tree will add more volume to the stem than the same increase in a short tree, so the increment in stem volume (or mass) peaks very late. Stephenson et al. challenge this paradigm, and suggest that mass increment increases continuously. Their analysis methods however are a textbook example of the 'ecological fallacy', and their conclusions therefore unsupported.

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Size‐mediated ageing reduces vigour in trees

Cited by 333 publications

References 29 publications

Indicadores del decaimiento en bosques de Nothofagus pumilio en el norte de la Patagonia, Argentina

Indicadores del decaimiento en bosques de Nothofagus pumilio en el norte de la Patagonia, Argentina

Relationships Between Tree Height and Carbon Isotope Discrimination

Rate of tree carbon accumulation increases continuously with tree size

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