Variability in leaf wettability and surface water retention of main species in semiarid Loess Plateau of China

Leaf wettability, adhesion or repulsion of water drops, varies greatly among species and plays an important role in plant–soil hydrological relations. This study aimed to examine the variability in leaf wettability among species in different habitats and growth periods, and their relationships with...

Full description

Saved in:
Bibliographic Details
Published inEcohydrology Vol. 11; no. 8
Main Authors Xiong, Peifeng, Chen, Zhifei, Jia, Zhao, Wang, Zhi, Palta, Jairo A., Xu, Bingcheng
Format Journal Article
LanguageEnglish
Published Oxford Wiley Subscription Services, Inc 01.12.2018
Subjects
Coefficient of variation
Coefficients
Contact angle
Drought
family
growth period
Growth stage
habitat
Hydrology
Interception
Interspecific
leaf wettability
Leaves
Plant cover
rainfall interception
Retention
Soil
Species
Surface water
surface water retention
Variability
Water drops
Wettability
China
Loess Plateau
Online AccessGet full text

Cover

More Information
Summary:Leaf wettability, adhesion or repulsion of water drops, varies greatly among species and plays an important role in plant–soil hydrological relations. This study aimed to examine the variability in leaf wettability among species in different habitats and growth periods, and their relationships with plant surface water retention in the semiarid Loess Plateau of China. The leaf adaxial and abaxial contact angles, the surface water retention of leaves and individual plants, and general plant traits of 68 species belonging to 28 families were examined from May to August in 2017. Results showed that leaf water contact angles ranged from 27.3° to 133.4° and leaves with higher contact angles normally had lower variation coefficients. Leaf wettability was affected by internal properties (including leaf side, family, and leaf age) and external conditions (growth period), whereas the life form and slope aspect did not show significant effects. There were 47 species having higher contact angles on adaxial than abaxial surfaces, and the differences were significant in 23 species. Gramineous and leguminous species were more unwettable than compositae and rosaceous species. New leaves were more unwettable than old leaves. Surface wettability increased from May–June to July–August period. Leaf wettability was positively correlated with leaf surface water retention and was the best predictor of individual plant surface water retention compared with other plant traits. Leaf wettability showed interspecific differences associated with family and growth stage and can be a considerable variable in predicting canopy interception and evaluating vegetation hydrological function in drought environments.
ISSN:1936-0584
1936-0592
DOI:10.1002/eco.2021