Unsaturated hydraulic properties of xerophilous mosses: towards implementation of moss covered soils in hydrological models

Voortman, Bernard R.; Bartholomeus, R.P.; Bodegom, Peter M. van; Gooren, Harm; Zee, S.E.A.T.M. van der; Witte, J.P.M.

doi:10.1002/hyp.10111

Cited by 25 publications

(43 citation statements)

References 34 publications

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“…Although organic layers, e.g., dry peat, have a larger specific heat (1600 J kg −1 K −1 ) than dry sand (693 J kg −1 K −1 ) (Gavriliev, 2004), the energy required to heat up the moss material is much smaller than for sand, because of the small dry bulk density of ca. 26.8 g L −1 (derived for Campylopus introflexus from Voortman et al, 2014). Therefore, the surface temperature and the emitted longwave radiation are largest for the moss surface.…”

Section: Net Longwave Radiationmentioning

confidence: 94%

“…This passive evaporation process is similar to the process of soil evaporation, i.e., evaporation becomes limited if the surface becomes too dry to deliver the potential rate. The unsaturated hydraulic properties of the dense Campylopus introflexes moss mat covering the lysimeter soil were based on the hydraulic properties derived by Voortman et al (2014) and used in the first 2 cm of the model domain. Macro pores in the moss mat were neglected by Voortman et al (2014), which implies that direct implementation of these hydraulic properties would result in large amounts of surface runoff generation or ponding, since the unsaturated hydraulic conductivity (K 0 ) of the moss mat is lower than 0.28 cm d −1 .…”

Section: Model Simulations Of Et Amentioning

confidence: 99%

“…The unsaturated hydraulic properties of the dense Campylopus introflexes moss mat covering the lysimeter soil were based on the hydraulic properties derived by Voortman et al (2014) and used in the first 2 cm of the model domain. Macro pores in the moss mat were neglected by Voortman et al (2014), which implies that direct implementation of these hydraulic properties would result in large amounts of surface runoff generation or ponding, since the unsaturated hydraulic conductivity (K 0 ) of the moss mat is lower than 0.28 cm d −1 . Therefore, the dual porosity model of Durner (1994) was used to add 1000 cm d −1 to the hydraulic conductivity curve of Voortman et al (2014) between −1 and 0 cm pressure head (Appendix A).…”

Section: Model Simulations Of Et Amentioning

confidence: 99%

“…Macro pores in the moss mat were neglected by Voortman et al (2014), which implies that direct implementation of these hydraulic properties would result in large amounts of surface runoff generation or ponding, since the unsaturated hydraulic conductivity (K 0 ) of the moss mat is lower than 0.28 cm d −1 . Therefore, the dual porosity model of Durner (1994) was used to add 1000 cm d −1 to the hydraulic conductivity curve of Voortman et al (2014) between −1 and 0 cm pressure head (Appendix A). This permits the infiltration of rainwater at high intensity rain showers without affecting the unsaturated hydraulic behavior at negative pressure heads.…”

Section: Model Simulations Of Et Amentioning

confidence: 99%

“…Mosses and lichens are present in most successional stages in dry dune ecosystems, either as pioneer species or as understory vegetation. Voortman et al (2014) hypothesized that moss-covered soils could evaporate less than a bare soil, since the unsaturated hydraulic properties of moss layers reduce evaporation under relatively moist conditions. Such hydraulic behavior could have large implications on the ecological interactions between vascular and nonvascular plants in water-limited ecosystems, as the presence of a moss cover could facilitate the water availability for rooting plants.…”

mentioning

confidence: 99%

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Quantifying energy and water fluxes in dry dune ecosystems of the Netherlands

Voortman

Bartholomeus

Zee

et al. 2015

Hydrol. Earth Syst. Sci.

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Abstract. Coastal and inland dunes provide various ecosystem services that are related to groundwater, such as drinking water production and biodiversity. To manage groundwater in a sustainable manner, knowledge of actual evapotranspiration (ET a ) for the various land covers in dunes is essential. Aiming at improving the parameterization of dune vegetation in hydrometeorological models, this study explores the magnitude of energy and water fluxes in an inland dune ecosystem in the Netherlands. Hydrometeorological measurements were used to parameterize the Penman-Monteith evapotranspiration model for four different surfaces: bare sand, moss, grass and heather. We found that the net longwave radiation (R nl ) was the largest energy flux for most surfaces during daytime. However, modeling this flux by a calibrated FAO-56 R nl model for each surface and for hourly time steps was unsuccessful. Our R nl model, with a novel submodel using solar elevation angle and air temperature to describe the diurnal pattern in radiative surface temperature, improved R nl simulations considerably. Model simulations of evaporation from moss surfaces showed that the modulating effect of mosses on the water balance is species-dependent. We demonstrate that dense moss carpets (Campylopus introflexus) evaporate more (5 %, +14 mm) than bare sand (total of 258 mm in 2013), while more open-structured mosses (Hypnum cupressiforme) evaporate less (−30 %, −76 mm) than bare sand. Additionally, we found that a drought event in the summer of 2013 showed a pronounced delayed signal on lysimeter measurements of ET a for the grass and heather surfaces, respectively. Due to the desiccation of leaves after the drought event, and their feedback on the surface resistance, the potential evapotranspiration in the year 2013 dropped by 9 % (−37 mm) and 10 % (−61 mm) for the grass and heather surfaces, respectively, which subsequently led to lowered ET a of 8 % (−29 mm) and 7 % (−29 mm). These feedbacks are of importance for water resources, especially during a changing climate with an increasing number of drought days. Therefore, such feedbacks need to be integrated into a coupled plant physiological and hydrometeorological model to accurately simulate ET a . In addition, our study showed that groundwater recharge in dunes can be increased considerably by promoting moss vegetation, especially of open-structured moss species.

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Section: Net Longwave Radiationmentioning

confidence: 94%

Section: Model Simulations Of Et Amentioning

confidence: 99%

Section: Model Simulations Of Et Amentioning

confidence: 99%

Section: Model Simulations Of Et Amentioning

confidence: 99%

mentioning

confidence: 99%

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Quantifying energy and water fluxes in dry dune ecosystems of the Netherlands

Voortman

Bartholomeus

Zee

et al. 2015

Hydrol. Earth Syst. Sci.

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Burn severity alters peatland moss water availability: implications for post‐fire recovery

et al. 2015

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Wildfire is the largest disturbance affecting northern peatlands; however, little is known about how burn severity (organic soil depth of burn) alters post-fire hydrological conditions that control the recovery of keystone peatland mosses (i.e. Sphagnum). For this reason, we assessed the impact of burn severity on moss water availability by measuring soil tension (Ψ ) and surface volumetric moisture content (θ) in burned and unburned portions of a peatland complex 2 years after fire. We found that both high and low burn severity decreased post-fire water availability by altering peat hydrophysical properties (moisture retention and water repellency). Locations covered by Sphagnum fuscum prior to fire exhibited a decreasing post-fire water availability with an increasing burn severity. In contrast, the lowest water availability (Ψ > 400 cm, θ < 0·02) was observed in feather mosses that underwent low burn severity (residual branches identifiable). Deep burning (>0·20 m) in peatland margins and burn depths >0·05 m in the middle of the peatland exhibited the highest water availability (Ψ < 60 cm). Locations with low surface θ and high Ψ , notably feather mosses undergoing low burn severity, exhibited minimal moss recolonization. Such areas dominate postfire surface cover (~40%) within late successional (mature) peatlands or peatlands located in dry hydrological settings. We argue that such environments are under-represented in conceptual models of post-fire recovery. A new conceptual model is proposed in which (1) deep burning is counterbalanced by rapid recolonization and (2) pre-fire species interact with burn severity to produce substantial lags in post-fire moss recovery.

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How the evaporation of dry dune grasslands evolves during the concerted succession of soil and vegetation

et al. 2017

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Sustainable water and vegetation management of coastal dunes requires fundamental knowledge of how interactions between soil, water, and vegetation evolve during succession. Therefore, we quantified the effect of succession on evaporation in dry dune grasslands of the Netherlands. OnIn general, the vascular plant cover is smaller and the succession speed is slower on equator-facing slopes, which are relatively dry.Mosses and lichens are present as pioneer species or as understory vegetation in coastal dunes. Because these mosses and lichens are more resilient to drought than most vascular plants, their cover is

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Unsaturated hydraulic properties of xerophilous mosses: towards implementation of moss covered soils in hydrological models

Cited by 25 publications

References 34 publications

Quantifying energy and water fluxes in dry dune ecosystems of the Netherlands

Quantifying energy and water fluxes in dry dune ecosystems of the Netherlands

Burn severity alters peatland moss water availability: implications for post‐fire recovery

How the evaporation of dry dune grasslands evolves during the concerted succession of soil and vegetation

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