Vegetation impacts soil water content patterns by shaping canopy water fluxes and soil properties

Vegetation impacts soil water content patterns by shaping canopy water fluxes and soil properties

Soil water content is a key variable for biogeochemical and atmospheric coupled processes. Its small‐scale heterogeneity impacts the partitioning of precipitation (e.g., deep percolation or transpiration) by triggering threshold processes and connecting flow paths. Forest hydrologists frequently hyp...

Full description

Saved in:
Bibliographic Details
Published in:Hydrological processes Vol. 31; no. 22; pp. 3783 - 3795
Main Authors: Metzger, Johanna Clara, Wutzler, Thomas, Dalla Valle, Nicolas, Filipzik, Janett, Grauer, Christoph, Lehmann, Robert, Roggenbuck, Martin, Schelhorn, Danny, Weckmüller, Josef, Küsel, Kirsten, Totsche, Kai Uwe, Trumbore, Susan, Hildebrandt, Anke
Format: Journal Article
Language:English
Published: Chichester Wiley Subscription Services, Inc 30-10-2017
Subjects:
Beech
Biogeochemistry
Canopies
Canopy
Channeling
Connecting
Deep percolation
Field capacity
Flow paths
Fluxes
Forests
Gravitation
Gravity
Heterogeneity
Hydraulic properties
Hydrologists
Hydrology
Macroporosity
Moisture content
Percolation
Precipitation
Precipitation patterns
Profiles
Properties
Rainfall
Rooting
Soil
Soil properties
Soil structure
Soil water
soil water retention
spatiotemporal patterns
stemflow
Subsoils
Throughfall
Topsoil
Transpiration
Trees
Water content
Wetting
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Soil water content is a key variable for biogeochemical and atmospheric coupled processes. Its small‐scale heterogeneity impacts the partitioning of precipitation (e.g., deep percolation or transpiration) by triggering threshold processes and connecting flow paths. Forest hydrologists frequently hypothesized that throughfall and stemflow patterns induce soil water content heterogeneity, yet experimental validation is limited. Here, we pursued a pattern‐oriented approach to explore the relationship between net precipitation and soil water content. Both were measured in independent high‐resolution stratified random designs on a 1‐ha temperate mixed beech forest plot in Germany. We recorded throughfall (350 locations) and stemflow (65 trees) for 16 precipitation events in 2015. Soil water content was measured continuously in topsoil and subsoil (210 profiles). Soil wetting was only weakly related to net precipitation patterns. The precipitation‐induced pattern quickly dissipates and returns to a basic pattern, which is temporally stable. Instead, soil hydraulic properties (by the proxy of field capacity) were significantly correlated with this stable soil water content pattern, indicating that soil structure more than net precipitation drives soil water content heterogeneity. Also, both field capacity and soil water content were lower in the immediate vicinity of tree stems compared to further away at all times, including winter, despite stemflow occurrence. Thus, soil structure varies systematically according to vegetation in our site. We conclude that enhanced macroporosity increases gravity‐driven flow in stem proximal areas. Therefore, although soil water content patterns are little affected by net precipitation, the resulting soil water fluxes may strongly be affected. Specifically, this may further enhance the channelling of stemflow to greater depth and beyond the rooting zone.
ISSN:0885-6087
1099-1085
DOI:10.1002/hyp.11274