Measurements and ecological implications of non‐rainfall water in desert ecosystems—A review

Kidron, Giora J.; Starinsky, Abraham

doi:10.1002/eco.2121

Cited by 45 publications

(60 citation statements)

References 289 publications

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“…Likewise, we are also inclined to suggest that the lush cover of soil lichens in the Tabernas is at least partially linked to the higher amounts and frequent occurrence of rain events and subsequently to the possible use of rainwater by these soil lichens (Lázaro, 2004). On the other hand, the low cover of soil lichens in the Negev cannot be linked to the frequent occurrence of dew but rather to the low amounts of rain (Kidron and Starinsky, 2019). This may explain the confinement of lichens to the feet of rock outcrops where they benefit from extra water by runoff (Fig.…”

Section: Discussionmentioning

confidence: 99%

Are coastal deserts necessarily dew deserts? An example from the Tabernas Desert

Kidron

Lázaro

2020

Journal of Hydrology and Hydromechanics

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Vapor condensation, whether due to dew or fog, may add a stable and important source of water to deserts. This was also extensively assessed in the Negev, regarded as a dew desert. Dew deserts necessitate a large reservoir of vapor, and are therefore confined to near oceans or seas. Yet, examples of such deserts are scarce. Here we try to assess whether the Tabernas Desert in SE Spain can be regarded as a dew desert, and may therefore facilitate the growth of certain organisms that otherwise would not survive the dry season. We analyze some of the abiotic conditions of four relatively dry months (June, July, August, September) in the Tabernas and Negev deserts (with the Negev taken as an example of a dew desert) during 2003–2012. The analysis showed substantially lower values of relative humidity (by 10–13%) in the Tabernas in comparison to the Negev, with RH ≥95% being on average only 0.9–1.1 days a month in the Tabernas in comparison to 9.7–13.9 days in the Negev. Our findings imply that the Tabernas Desert cannot be regarded as a dew desert, suggesting that rain will be the main factor responsible for the food web chain in the Tabernas.

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Section: Discussionmentioning

confidence: 99%

Are coastal deserts necessarily dew deserts? An example from the Tabernas Desert

Kidron

Lázaro

2020

Journal of Hydrology and Hydromechanics

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“…Highlands: limestone hills with loessial wadis (a), lithobionts (lichens) covering the bedrocks while cyanobacterial crusts (with lichens confined to the feet of the bedrocks) covering the loessial soil (b), lithoibionts (epilithic and endolithic lichens) covering cobbles (c), measurements of the nonrainfall water (NRW) at the soil surface, at the cobbles and the glass plates, CPM (d), and measurements of temperatures on the cobble, the soil surface, and in the air, at 10-cm height above ground (e) (1970b) also applies to other Negev lichens. An amount of 0.05 mm was found necessary to facilitate net photosynthesis of R. maciformis (Kidron & Starinsky, 2019). This is half the amount necessary for vapour condensation (0.1 mm; Lange et al, 1992), which also marks the threshold between a visibly wet and a dry surface (Kidron, Herrnstadt, & Barzilay, 2002).…”

Section: F I G U R E 1 General View Of the Negevmentioning

confidence: 92%

“…By adjacently attaching identical‐size pieces of cloths and R. maciformis thalli to different rock and cobble surfaces, calibration between NRW adsorbed by the cloths and thalli allowed to determine the threshold amount of water necessary to reactivate the photosynthetic apparatus of R. maciformis , which according to Lange et al () also applies to other Negev lichens. An amount of 0.05 mm was found necessary to facilitate net photosynthesis of R. maciformis (Kidron & Starinsky, ). This is half the amount necessary for vapour condensation (0.1 mm; Lange et al, ), which also marks the threshold between a visibly wet and a dry surface (Kidron, Herrnstadt, & Barzilay, ).…”

Section: Introductionmentioning

confidence: 99%

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Assessing the likelihood of the soil surface to condense vapour: The Negev experience

Kidron

Kronenfeld

2020

Ecohydrology

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The likelihood of dew to provide water to cyanobacteria (CB) and crustose lichens (CL) on soil is a matter of great controversy. Although vapour condensation takes place on cobbles of the Negev Highlands, facilitating lush cover of CL, controversy exists regarding the possible contribution of dew to CB and CL inhabiting the loessial soil of the Negev Highlands. To evaluate this matter, temperature, and measurements of the nonrainfall water (NRW) were conducted during the dewy season (August–November 2019). They included periodical NRW measurements using cloths attached to the (a) soil surface, (b) on top of 10 × 10 × 5‐ to 6‐cm cobbles, and (c) on 10 × 10 × 0.2‐cm glass plates (the cloth‐plate method, CPM). Additionally, temperature measurements took place at the soil and the cobble surfaces and in the air at 10‐cm height above ground. Air temperature and the relative humidity measured by an adjacent meteorological station facilitated the calculation of the dew‐point temperature (Td). Taking the CPM as reference, 24 mornings with NRW ≥0.03 mm (the threshold of lichen metabolism) were recorded. Vapour condensation, that is, NRW ≥0.1 mm were recorded during 16 mornings on the cobbles (with a maximum of 0.21 mm) but never on the soil, where maximum NRW reached only 0.023 mm. Surface temperature never reached Td. We therefore conclude that unlike lithic lichens that inhabit bedrocks and cobbles in the Negev Highlands, dew cannot be regarded as a meaningful direct source of water for CB or CL biocrusts on soil.

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“…, and biological soil crusts (Jia et al, 2014;Kidron & Starinsky, 2019;Lange, Geiger, & Schulze, 1977;Pan, Wang, Zhang, & Hu, 2018;Prado & Sancho, 2007;Rao et al, 2009;Sun et al, 2008;Tao & Zhang, 2012;Temina & Kidron, 2015;Xiao et al, 2019;Zhang et al, 2009) are mainly from non-rainfall water inputs, such as fog, dew, and water vapor adsorption (Kaseke et al, 2012;, which are three main mechanisms of adding moisture to the uppermost soil surfaces of the different types of deserts ( Figure 1).…”

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confidence: 99%

Variations in dew moisture regimes in desert ecosystems and their influencing factors

Zhang

et al. 2020

WIREs Water

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As an important source of non-rainfall input of land-surface liquid water, dew has considerable ecological and hydrological significance in desert ecosystems. Dew moisture regime is commonly used for characterizing available dew. It discloses not only the contributions of dew to plants, small animals, and biological crusts but also the mechanism by which desert organisms adapt to extreme climates. By reviewing the existing researches on dew moisture regimes in desert ecosystems, this study reveals the variations in the amount and duration of dew, as well as its influencing factors at site-, catchment-, and regional scales, based on the radiation cooling theory and the physical mechanisms of dew formation. Furthermore, it compares the differences in dew moisture between various sites and catchments, illustrates the trends in daily and annual dew moisture in various deserts, and identifies the existing problems of researches on dew moisture regimes amid climate change. The findings of this study enhance preliminary knowledge on the reasonable utilization of dew water, worldwide.

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Measurements and ecological implications of non‐rainfall water in desert ecosystems—A review

Cited by 45 publications

References 289 publications

Are coastal deserts necessarily dew deserts? An example from the Tabernas Desert

Are coastal deserts necessarily dew deserts? An example from the Tabernas Desert

Assessing the likelihood of the soil surface to condense vapour: The Negev experience

Variations in dew moisture regimes in desert ecosystems and their influencing factors

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