par Butler, Andre A.J.;Barbier, Nicolas Serge 
;Čermák, Jan;Koller, Jan A N J.;Thornily, C.;Mcevoy, Colin;Nicoll, Bruce;Perks, Mike M.P.;Grace, John McFero J.;Meir, Patrick
Référence Tree physiology, 30, 6, page (705-714)
Publication Publié, 2010-06
;Čermák, Jan;Koller, Jan A N J.;Thornily, C.;Mcevoy, Colin;Nicoll, Bruce;Perks, Mike M.P.;Grace, John McFero J.;Meir, PatrickRéférence Tree physiology, 30, 6, page (705-714)
Publication Publié, 2010-06
Article révisé par les pairs
| Résumé : | Our knowledge of the nature of belowground competition for moisture and nutrients is limited. In this study, we used an earth impedance method to determine the root absorbing area of Sitka spruce (Picea sitchensis (Bong.) Carr.) trees, making measurements in stands of differing density (2-, 4- and 6-m inter-tree spacing). We compared absorbing root area index (RAIabsorbing; based on the impedance measure) with fine root area index (RAIfine; based on estimates of total surface area of fine roots) and related these results to investment in conductive roots. Root absorbing area was a near-linear function of tree stem diameter at 1.3 m height. At the stand level, RAIabsorbing, which is analogous to and scaled with transpiring leaf area index (maximum stomatal pore area per unit ground area; LAItranspiring), increased proportionally with basal area across the three stands. In contrast, RAIfine was inversely propotional to basal area. The ratio of RAIabsorbing to LAItranspiring ranged from 7.7 to 17.1, giving an estimate of the relative aboveground versus belowground resource exchange areas. RAIabsorbing provides a way of characterizing ecosystem functioning as a physiologically meaningful index of belowground absorbing area. © The Author 2010. Published by Oxford University Press. All rights reserved. |
