Philip W. Wes

Forest Research Centre, Southern Cross University, Lismore, Australi

Primary production;Photosynthesis;Respiration;Biomass growth;Ageing;FINE-ROOT BIOMASS;WOODY-TISSUE RESPIRATION;NET PRIMARY PRODUCTION;LIGHT USE EFFICIENCY;SCOTS PINE STANDS;HYDRAULIC LIMITATION HYPOTHESIS;LEAF DRY MASS;TREE HEIGHT;PONDEROSA PINE;PHOTOSYNTHETIC CAPACIT

Once forests have achieved a full canopy, their growth rate declines progressively with age. This work used a global data set with estimates from a wide range of forest types, aged 20-795 years, of their annual photosynthetic production (gross primary production, GPP) and subsequent above- plus below-ground biomass production (net primary production, NPP). Both GPP and NPP increased with increasing mean annual temperature and precipitation. GPP was then unrelated to forest age whilst NPP declined progressively with increasing age. These results implied that autotrophic respiration increases with age. It has been proposed that GPP should decline in response to increasing water stress in leaves as water is raised to greater heights as trees grow taller with age. However, trees may make substantial plastic adjustment in morphology and anatomy of newly developing leaves, xylem and fine roots to compensate for this stress and maintain GPP with age. This work reviews the possibilities that NPP declines with age as respiratory costs increase progressively in, any or all of, the construction and maintenance of more complex tissues, the maintenance of increasing amounts of live tissue within the sapwood of stems and coarse roots, the conversion of sapwood to heartwood, the increasing distance of phloem transport, increased turnover rates of fine roots, cost of supporting very tall trees that are unable to compensate fully for increased water stress in their canopies or maintaining alive competitively unsuccessful small trees.