Influence of soil, land use and climatic factors on the hydraulic conductivity of soil

• Main Authors: N. Jarvis, J. Koestel, I. Messing, J. Moeys, A. Lindahl
• Format: Article
• Language: English
• Published: Copernicus Publications 2013-12-01
• Series: Hydrology and Earth System Sciences
• Online Access: http://www.hydrol-earth-syst-sci.net/17/5185/2013/hess-17-5185-2013.pdf
• ISSN: 1027-5606; 1607-7938

Due to inadequate data support, existing algorithms used to estimate soil hydraulic conductivity, <i>K</i>, in (eco)hydrological models ignore the effects of key site factors such as land use and climate and underplay the significant effects of soil structure on water flow at and near saturation. These limitations may introduce serious bias and error into predictions of terrestrial water balances and soil moisture status, and thus plant growth and rates of biogeochemical processes. To resolve these issues, we collated a new global database of hydraulic conductivity measured by tension infiltrometer under field conditions. The results of our analyses on this data set contrast markedly with those of existing algorithms used to estimate <i>K</i>. For example, saturated hydraulic conductivity, <i>K</i>_s, in the topsoil (< 0.3 m depth) was found to be only weakly related to texture. Instead, the data suggests that <i>K</i>_s depends more strongly on bulk density, organic carbon content and land use. In this respect, organic carbon was negatively correlated with <i>K</i>_s, presumably due to water repellency, while <i>K</i>_s at arable sites was, on average, ca. 2–3 times smaller than under natural vegetation, forests and perennial agriculture. The data also clearly demonstrates that clay soils have smaller <i>K</i> in the soil matrix and thus a larger contribution of soil macropores to <i>K</i> at and near saturation.