GEOLOGICAL CHARACTERISTICS OF DESERT AND UPPER DESERT CAVES (NE BLUE DIAMOND HILL, NEVADA, USA
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GEOLOGICAL CHARACTERISTICS OF DESERT AND UPPER DESERT CAVES (NE BLUE DIAMOND HILL, NEVADA, USA ABSTRACT Desert Cave (72 m) in Upper Desert Cave (62 m) sta najdaljši znani jami na Blue Diamond Hill in se nahajata znotraj enega od več kanjonov. Jami sta razviti v apnencu iz zgornjega dela spodnjega permija (Kaibab formacija). V najnižjem delu Desert Cave, ki je 12,6 m globoka, jamski rov doseže litološko mejo med Kaibab apnencem in sedimentacijsko brečo (spodnji del Kaibab formacije). Stik breča-apnenec je ena od inicialnih struktur iz freatičnega obdobja razvoja jame, vendar ne pred mezozojskimi narivnimi deformacijami. Površinska razdalja med vhodoma v Desert in Upper Desert Cave je 81 m, jami nista povezani. Desert Cave se nahaja 2 km zahodno od nariva Bird Spring. Prevladujoče smeri razpok v jami so NW-SE in NE-SW. Smer rova je skoraj vzporedna s smerjo razpok NE-SW. Obstaja jasna povezava med javljanjem podorov v jami in moćneje izraženimi razpokami v smeri NW-SE. Desert Cave (72 m) and Upper Desert Cave (62 m) are the longest known caves in Blue Diamond Hill and are situated in one of its canyons. Caves are developed in limestone of latest early Permian age (Kaibab formation). In lowest part of Desert Cave, which is 12,6 m deep, cave passage reaches lithological contact between Kaibab limestone and sedimentary breccia (lower part of Kaibab formation). The contact breccia-limestone is one of initial structures in phreatic period of cave development but not before Mesozoic thrusting tectonics. Surface distance between entrances to Desert and Upper Desert Cave is 81 m, the caves are not connected. Desert Cave is situated 2 km W from Bird Spring thrust. Prevailing fissure directions in the cave are NW-SE and NE-SW. Passage direction is almost parallel with the NE-SW fissures direction. There is obvious connection in occurrence of breakdown in the cave with strongly expressed fissures in NW-SE direction. Precipitation pulses and soil CO2 flux in a Sonoran Desert ecosystem Abstract Precipitation is a major driver of biological processes in arid and semiarid ecosystems. Soil biogeochemical processes in these water‐ limited systems are closely linked to episodic rainfall events, and the relationship between microbial activity and the amount and timing of rainfall has implications for the whole‐ system carbon (C) balance. Here, the influences of storm size and time between events on pulses of soil respiration were explored in an upper Sonoran Desert ecosystem. Immediately following experimental rewetting in the field, CO2 efflux increased up to 30‐ fold, but generally returned to background levels within 48 h. CO2 production integrated over 48 ranged from 2.5 to 19.3 C g h m−2 and was greater beneath shrubs than in interplant spaces. When water was applied on sequential days, postwetting losses of CO2 were only half a large as initial fluxes, and the size of the second pulse increased with time between consecutive events. Soil respiration was more closely linked to the organic matter content of surface soils than to rainfall amount. Beneath shrubs, rates increased nonlinearly with storm size, reaching an asymptote at approximately 0.5 cm simulated storms. This nonlinear relationship stems from (1) resource limitation of microbial activity that is manifest at small time scales, and (2) greatly reduced process rates in deeper soil strata. Thus, beyond some threshold in storm size, increasing the duration or depth of soil moisture has little consequence for short‐ term losses of CO2. In addition, laboratory rewetting across a broad range in soil water content suggest that microbial activity and CO2 efflux following rainfall may be further modified by the routing and redistribution of water along hillslopes. Finally, analysis of long‐ term precipitation data suggests that half the monsoon storms in this system are sufficient to induce soil heterotrophic activity and C losses, but are not large enough to elicit autotrophic activity and C accrual by desert shrubs. A proposed mechanism for the formation of ‘Fertile Islands’ in the desert ecosystem Movement of nitrogen atoms throughout the environment occurs by (1) physical transport such as molecular diffusion and hydrodynamic flow, mechanisms that always disperse and (2) biological transport such as sap flow and animal movement, mechanisms that most often lead to concentration. Both types of transport are accelerated by moisture, but the physical mechanisms are more sensitive. In the desert ecosystem, micro-, meso-, and macro-fauna are all attracted to the canopies of whatever plants exist, the place of highest moisture, lowest daytime temperature and most abundant food sources. This paper presents the hypothesis that under conditions of desert aridity the concentrating biological transport mechanisms dominate over the dispersive physical mechanisms. This causes the phenomenon known as ‘fertile islands.’ Soil Properties in a Mesquite-Dominated Sonoran Desert Ecosystem Abstract Soil was collected in 30-cm depth increments to 90 cm from beneath Prosopis glandulosaTorr. var. glandulosa (L. Benson) M. C. Jtn. (mesquite) and from the nonvegetated area between mesquite trees in a phreatophytic stand in the Sonoran Desert of southern California. Total N, NO -3-N, NH+4-N, organic C, NaHCO3-extractable PO3-4-P, and saturation extract K+were significantly higher beneath mesquite, while Na+ and Cl- were significantly higher between mesquite trees. Differences in pH, the osmotic potential of saturation extracts, saturation percent, and SO 2-4-S were nonsignificant. Large amounts of N (1.68 g kg−1 of soil) have accumulated in the surface 30 cm beneath mesquite. This N most likely had been symbiotically fixed by mesquite. Over 20% of the N in this ecosystem occurred as NO -3. This unusual NO-3 accumulation was possible since leaching and denitrification were probably limited by aridity. The Na+ adsorption ratio of saturation extracts (SAR), 0–30 cm, was significantly lower at the center of tree canopies (7.9) than in soil between trees (17.3) and also was lower than the groundwater (12.7). Foliar analysis indicated mesquite was excluding Na +. Consequently, the decomposition of mesquite litter produced a soil with a lower SAR than the nonvegetated soil. Soil N was determined at six additional Sonoran Desert sites. Nitrogen accumulation beneath mesquite was related to soil texture and water regime. Total soil N was highest on low relief phreatophytic sites with high clay content (1.34 g of N kg−1 of soil, 0–15 cm) and lowest in aeolian sand dunes (0.18 g of N kg −1 of soil, 0–15 cm). Woody legumes such as mesquite, through the accumulation of symbiotically fixed N and the accretion of other nutrients in the surface beneath their canopies, may be important in maintaining the long-term productivity of some desert ecosystems. Precipitation pulses and soil CO2 flux in a Sonoran Desert ecosystem Abstract Precipitation is a major driver of biological processes in arid and semiarid ecosystems. Soil biogeochemical processes in these water‐ limited systems are closely linked to episodic rainfall events, and the relationship between microbial activity and the amount and timing of rainfall has implications for the whole‐ system carbon (C) balance. Here, the influences of storm size and time between events on pulses of soil respiration were explored in an upper Sonoran Desert ecosystem. Immediately following experimental rewetting in the field, CO2 efflux increased up to 30‐ fold, but generally returned to background levels within 48 h. CO2 production integrated over 48 ranged from 2.5 to 19.3 C g h m−2 and was greater beneath shrubs than in interplant spaces. When water was applied on sequential days, postwetting losses of CO2 were only half a large as initial fluxes, and the size of the second pulse increased with time between consecutive events. Soil respiration was more closely linked to the organic matter content of surface soils than to rainfall amount. Beneath shrubs, rates increased nonlinearly with storm size, reaching an asymptote at approximately 0.5 cm simulated storms. This nonlinear relationship stems from (1) resource limitation of microbial activity that is manifest at small time scales, and (2) greatly reduced process rates in deeper soil strata. Thus, beyond some threshold in storm size, increasing the duration or depth of soil moisture has little consequence for short‐ term losses of CO2. In addition, laboratory rewetting across a broad range in soil water content suggest that microbial activity and CO2 efflux following rainfall may be further modified by the routing and redistribution of water along hillslopes. Finally, analysis of long‐ term precipitation data suggests that half the monsoon storms in this system are sufficient to induce soil heterotrophic activity and C losses, but are not large enough to elicit autotrophic activity and C accrual by desert shrubs.
