Stand Structure and Allometry of Trees During Self-Thinning of Pure Stands

Stand Structure and Allometry of Trees During Self-Thinning of Pure Stands

(1) Stand structure and mean weight-density relations of nearly pure, dense, even-aged, natural stands of Prunus pensylvanica and Abies balsamea in the north-eastern U.S.A. were examined and related to allometric growth. Values for the exponents of allometric and mean weight-density equations were e...

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Bibliographic Details
Published in:The Journal of ecology Vol. 66; no. 2; pp. 599 - 614
Main Authors: Mohler, C. L., Marks, P. L., Sprugel, D. G.
Format: Journal Article
Language:English
Published: Oxford, etc Blackwell Scientific Publications 01-07-1978
Blackwell Scientific Pub
Subjects:
Forest ecology
Forest stands
Frequency distribution
Leaves
Plant roots
Plant thinning
Plants
Stand structure
Tree trunks
Trees
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Summary:(1) Stand structure and mean weight-density relations of nearly pure, dense, even-aged, natural stands of Prunus pensylvanica and Abies balsamea in the north-eastern U.S.A. were examined and related to allometric growth. Values for the exponents of allometric and mean weight-density equations were estimated by principal components analysis of logarithmically transformed data. (2) It is proposed that soon after a stand of woody plants becomes established the size frequency distribution is a negatively skewed, bell-shaped curve; the distribution subsequently becomes positively skewed, and eventually approaches normality after substantial thinning. Maximum positive skewness occurs at the time self-thinning begins. (3) The weight-frequency distribution undergoes a parallel series of stages: roughly normal at first, but quickly changing to lognormal, with maximum skewness attained at the time thinning begins. These curve-forms are proposed only as approximations to empirically observed distributions. A consistent tendency toward bimodality is one commonly-observed departure from the idealized distributions. (4) The calculated exponents of the mean weight-density equations for Prunus pensylvanica and Abies balsamea were -1.46 and -1.22, as compared to the proposed value of -1.5 (-3/2 power `law' of self-thinning). In general, weight changes in plant parts during self-thinning did not parallel those for whole plants; in particular, the mean weight-density exponent for foliage was approximately -1.0. The exponents of mean weight-density equations for total roots and total shoots, however, approximately equalled the exponent for whole plants. (5) It is concluded that observed patterns of allometric growth are incompatible with mean weight-density equations for whole plants, unless a mutual adjustment between allometry and stand structure is assumed.
ISSN:0022-0477
1365-2745
DOI:10.2307/2259153