The dynamics of wood productivity on drained peatland sites was analyzed fr
om the covariance structure generated by stand yield data of repeatedly mea
sured permanent sample plots in 81 Scots pine (Pinus sylvestris L.) or Norw
ay spruce (Picea abies Karst. (L.)) stands with admixtures of birch (Betula
pubescens Ehrh.). The site production potential, considered a latent varia
ble, was assumed to follow an autoregressive process over time elapsed sinc
e drainage. As a measure of the latent variable, a relative growth rate (RG
R) index was determined for all stands at the time of drainage and at four
successive measurement time points following drainage ton average 16, 23, 3
0, and 41 years). The index was calculated as the site index of an upland c
onifer stand with the ratio of periodic volume growth and standing volume a
nd adjusted by changes in stand stocking and thinning. The observed covaria
nce structure was described by fitting a structural equation model to the d
ata of RGR indices. When only the post-drainage measurement times were incl
uded, a quasi-simplex model with equal error variances and equal structural
parameters at different measurement times fit the data well indicating a p
ermanent covariance structure among the different measurements. Including t
he measurement at the time of drainage resulted in a non-permanent structur
e. The stand parameters at the time of drainage were poorly correlated with
post-drainage growth.
A considerable increase in the wood productivity of the sites was observed,
being greatest during twenty years after drainage and continuing up to 40
years since drainage. This was concluded to be due to changes in site prope
rties rather than stand structure although the effects of the single factor
s could not be analytically separated from one another. Our modelling appro
ach appeared to improve long-term site productivity estimates based merely
on botanical site indices.