Effects of soil texture and precipitation on above‐ground net primary productivity and vegetation structure across the Central Grassland region of the United States

Lane, Diana; Coffin, Debra P.; Lauenroth, William K.

doi:10.2307/3237123

Cited by 108 publications

(82 citation statements)

References 37 publications

(52 reference statements)

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“…Among the most noticeable hypotheses is the inverse-texture hypothesis (ITH) [Noy-Meir, 1973], which states that production is higher on coarse-textured soils than that on fine-textured soils in dry regions because the water availability will be high in coarse soil in dry regions. The hypothesis has been supported by many studies [e.g., Sala et al, 1988;Lane et al, 1998;Epstein et al, 1997]. According to observations from central grassland regions in the United States, sandy soils are more productive than loamy soils when annual precipitation is less than 370 mm [Sala et al, 1988].…”

Section: Introductionmentioning

confidence: 50%

See 1 more Smart Citation

Soil hydrological properties regulate grassland ecosystem responses to multifactor global change: A modeling analysis

Weng¹,

Luo²

2008

J. Geophys. Res.

106

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[1] We conducted a modeling study to evaluate how soil hydrological properties regulate water and carbon dynamics of grassland ecosystems in response to multifactor global change. We first calibrated a process-based terrestrial ecosystem (TECO) model against data from two experiments with warming and clipping or doubled precipitation in Great Plains. The calibrated model was used to simulate responses of soil moisture, evaporation, transpiration, runoff, net primary production (NPP), ecosystem respiration (R h ), and net ecosystem production (NEP) to changes in precipitation amounts and intensity, increased temperature, and elevated atmospheric [CO 2 ] along a soil texture gradient (sand, sandy loam, loam, silt loam, and clay loam). Soil available water capacity (AWC), which is the difference between field capacity and wilting point, was used as the index to represent soil hydrological properties of the five soil texture types. Simulation results showed that soil AWC altered partitioning of precipitation among runoff, evaporation, and transpiration, and consequently regulated ecosystem responses to global environmental changes. The fractions of precipitation that were used for evaporation and transpiration increased with soil AWC but decreased for runoff. High AWC could greatly buffer water stress during long drought periods, particularly after a large rainfall event. NPP, R h , and NEP usually increased with AWC under ambient and 50% increased precipitation scenarios. With the halved precipitation amount, NPP, R h , and NEP only increased from 7% to 7.5% of AWC followed by declines. Warming and CO 2 effects on soil moisture, evapotranspiration, and runoff were magnified by soil AWC. Regulatory patterns of AWC on responses of NPP, R h , and NEP to warming were complex. In general, CO 2 effects on NPP, R h , and NEP increased with soil AWC. Our results indicate that variations in soil texture may be one of the major causes underlying variable responses of ecosystems to global changes observed from different experiments.Citation: Weng, E., and Y. Luo (2008), Soil hydrological properties regulate grassland ecosystem responses to multifactor global change: A modeling analysis,

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Section: Introductionmentioning

confidence: 50%

“…In central grassland region of U.S.A., the soil texture ranged from sand and sandy loam to silt loam and silt clay loam. Soil water holding capacity among those soil types ranged from 0.062 to 0.33 g water g À1 soil [Lane et al, 1998]. We assigned five soil texture types to cover the whole range in nature.…”

Section: G03003mentioning

confidence: 99%

Soil hydrological properties regulate grassland ecosystem responses to multifactor global change: A modeling analysis

Weng¹,

Luo²

2008

J. Geophys. Res.

106

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“…In the Haut-Saint-Laurent, in Quebec, Meilleur et al (1992) observed no effect of soil texture on vegetation. In a steppe in the USA, more shrub species were found in intermediate soil textures, whereas more herbaceous species were encountered when soil texture was finer (Dodd and Lauenroth 1997;Lane et al 1998). However, even in these studies, soil texture did not have a significant effect on the aboveground net primary production (Lane et al 1998).…”

Section: Influence Of Dominant Vegetation Height and Density On The Amentioning

confidence: 97%

Factors Influencing the Abundance of Berry Plants for Black Bears, <em>Ursus americanus</em>, in Quebec

2008

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Berries generally represent the primary food source used by Black Bears (Ursus americanus) during summer and sometimes fall. Our study attempted to identify factors influencing the abundance of these critical resources for Black Bears in Quebec. We used data from the ecological inventories of the Ministère de l’Environnement du Québec. Three different study areas were selected, including the Papineau-Labelle Wildlife Reserve (326 sample plots; 24 species), the Laurentides Wildlife Reserve (679 sample plots; 16 species) and the Côte-Nord administrative region (1944 sample plots; 30 species). Each site represented a different bioclimatic domain. Characteristics of the dominant vegetation (density and height), soil texture, and drainage classes (vertical or oblique) were used as analysis factors. In general, height and density of the dominant vegetation had a significant effect on the abundance of berry plants. Berry plants were more abundant in plots where dominant vegetation height and density were low. Soil texture had little effect on the abundance of berry plants, and the influence of drainage varied depending on the region. This study allowed us to determine the optimal sites of berry resources for Black Bears.

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“…In coarse soils forbs and shrubs made up a larger proportion of total productivity as compared to fine-textured sites. Thus across a regional precipitation gradient, soil texture may play a larger role in determining community composition than in determining total ANPP (Lane et al, 1998) …”

Section: Biomass Productivity 41 Factors That Influence Savanna Prodmentioning

confidence: 99%

Invasive Plant Species and Biomass Production in Savannas

Mworia¹

2011

Biomass and Remote Sensing of Biomass

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Effects of soil texture and precipitation on above‐ground net primary productivity and vegetation structure across the Central Grassland region of the United States

Cited by 108 publications

References 37 publications

Soil hydrological properties regulate grassland ecosystem responses to multifactor global change: A modeling analysis

Soil hydrological properties regulate grassland ecosystem responses to multifactor global change: A modeling analysis

Factors Influencing the Abundance of Berry Plants for Black Bears, <em>Ursus americanus</em>, in Quebec

Invasive Plant Species and Biomass Production in Savannas

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