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Influence of rocks on soil temperature, soil water potential, and rooting patterns for desert succulents (1992)

Nobel, Park S. ; Miller, Patsy M. ; Graham, Eric A.

Springer

Oecologia 92 (1992), S. 90-96

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ISSN: 1432-1939

Keywords: Agave ; Cactus ; Root morphology ; Sonoran Desert ; Water potential

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Summary At a site in the Sonoran Desert, subterranean rocks and exposed boulders affected soil water potential as well as root morphology and distribution. For Agave deserti, the number of lateral roots per unit length of main root was 11 times higher under rocks and six times higher alongside rocks than in rock-free regions. Total root length per unit soil volume for Echinocereus engelmannii averaged 3-fold higher within 1 cm of boulders than 5 cm away, where the soil was drier. The total length of lateral roots per unit length of main root for Ferocactus acanthodes was 4.2 m m−1 under rocks but only 0.8 m m−1 in rock-free regions. The number of lateral roots per unit length of main root for Opuntia acanthocarpa was 7-fold higher alongside rocks than in rock-free regions and even higher under rocks. For transplanted and watered A. deserti, the number of new main roots produced per 1–2 month interval averaged 13 for five plants on the north side of boulders, 8 on the south side, 11 for five plants with half of their roots under rocks, 2 for those with half of their roots over rocks, and 3 for the control plants without rocks. Laboratory experiments showed that the soil water potential under rocks for 10 and 30 mm waterings stayed above −0.5 MPa for 13 and 19 d longer, respectively, than for regions away from rocks. The shortwave absorptance of granitic rocks from the field site was 0.82, the thermal conductivity coefficient was 1.50 W m−1 °C−1, and the volumetric heat capacity was 1.75 MJ m−3 °C−1. Field measurements indicated that 5-cm-thick buried rocks decreased the diel variation in soil temperatures on their undersurface by only 0.4° C compared with soil. Thus, the primary influence of rocks at the field site on root proliferation and branching for the four species was apparently caused by influences on soil water content.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00317267

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Leaf expansion, net CO2 uptake, Rubisco activity, and efficiency of long-term biomass gain for the common desert subshrub Encelia farinosa (1998)

Nobel, Park S. ; Zhang, Hehui ; Sharifi, Rasoul ; [et al.]

Springer

Photosynthesis research 56 (1998), S. 67-73

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ISSN: 1573-5079

Keywords: biomass productivity ; brittlebush ; leaf development ; photosynthetic capacity ; Sonoran Desert

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Encelia farinosa is one of the most abundant and highly studied species of the Sonoran Desert, yet characteristics of its leaf development and long-term photosynthetic capacity are relatively unknown. The net CO2 uptake rate and the Rubisco activity per unit leaf area for E. farinosa in a glasshouse increased in parallel for about 18 days after leaf emergence (leaf area was then 5 cm2), after which both were constant, suggesting that Rubisco levels controlled net CO2 uptake. Instantaneous net CO2 uptake rates at noon for well-watered E. farinosa in the glasshouse at different temperatures and light levels correctly predicted differences in daily net CO2 uptake at four seasonally diverse times for transplanted plants under irrigated conditions in the field but overpredicted the daily means by 13%. After this correction, seasonally adjusted net CO2 uptake per unit leaf area multiplied by the estimated monthly leaf area predicted that 42% of the net carbon gain was incorporated into plant dry weight over a 17-month period. The ecological success of E. farinosa apparently reflects an inherently high daily net CO2 uptake and retention of a substantial fraction of its leaf carbon gain.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1006079631961

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