Tiegs Scott D, Akinwole Philips O, Gessner Mark O
Department of Aquatic Ecology, Eawag: Swiss Federal Institute of Aquatic Science and Technology, Kastanienbaum, Switzerland.
Oecologia. 2009 Aug;161(2):343-51. doi: 10.1007/s00442-009-1386-x. Epub 2009 Jun 6.
Spatial scale is a critical consideration for understanding ecological patterns and controls of ecological processes, yet very little is known about how rates of fundamental ecosystem processes vary across spatial scales. We assessed litter decomposition in stream networks whose inherent hierarchical nature makes them a suitable model system to evaluate variation in decay rates across multiple spatial scales. Our hypotheses were (1) that increasing spatial extent adds significant variability at each hierarchical level, and (2) that stream size is an important source of variability among streams. To test these hypotheses we let litter decompose in four riffles in each of twelve 3rd-order streams evenly distributed across four 4th-order watersheds, and in a second experiment determined variation in decomposition rate along a stream-size gradient ranging from orders 1 to 4. Differences in decay rates between coarse-mesh and fine-mesh litter bags accounted for much of the overall variability in the data sets, and were remarkably consistent across spatial scales and stream sizes. In particular, variation across watersheds was minor. Differences among streams and among riffles were statistically significant, though relatively small, leaving most of the total variance (51%) statistically unexplained. This result suggests that variability was generated mainly within riffles, decreasing successively with increasing scale. A broad range of physical and chemical attributes measured at the study sites explained little of the variance in decomposition rate. This, together with the strong mesh-size effect and greater variability among coarse-mesh bags, suggests that detritivores account, at least partly, for the unexplained variance. These findings contrast with the widespread perception that variability of ecosystem characteristics, including process rates, invariably increases (1) with spatial extent and (2), in stream networks, when analyses encompass headwaters of various size. An important practical implication is that natural variability need not compromise litter decomposition assays as a means of assessing functional ecosystem integrity.
空间尺度是理解生态格局和生态过程控制的关键因素,然而对于基本生态系统过程的速率如何随空间尺度变化,我们却知之甚少。我们评估了溪流网络中的凋落物分解情况,溪流网络固有的层次性质使其成为评估多个空间尺度上分解速率变化的合适模型系统。我们的假设是:(1)空间范围的增加会在每个层次水平上增加显著的变异性;(2)溪流大小是溪流间变异性的一个重要来源。为了验证这些假设,我们在均匀分布于四个四阶流域的十二条三阶溪流中的每一条溪流的四个浅滩中放置凋落物进行分解,并在第二个实验中确定了沿着从一阶到四阶的溪流大小梯度的分解速率变化。粗网袋和细网袋中凋落物分解速率的差异占数据集总体变异性的很大一部分,并且在空间尺度和溪流大小上都非常一致。特别是,流域间的差异很小。溪流间和浅滩间的差异具有统计学意义,尽管相对较小,使得总方差的大部分(51%)在统计学上无法解释。这一结果表明变异性主要在浅滩内产生,并随着尺度的增加而依次减小。在研究地点测量的广泛的物理和化学属性对分解速率的方差解释很少。这一点,再加上强烈的网目大小效应以及粗网袋间更大的变异性,表明碎屑食性动物至少部分地解释了无法解释的方差。这些发现与普遍的观念形成对比,即包括过程速率在内的生态系统特征的变异性总是(1)随着空间范围的增加而增加,以及(2)在溪流网络中,当分析涵盖各种大小的源头时也是如此。一个重要的实际意义是,自然变异性不一定会影响将凋落物分解测定作为评估生态系统功能完整性的一种手段。
