Downstream trends in sediment size and composition of channel-bed, bar, and bank deposits related to hydrologic and lithologic controls in the Llano River watershed, central Texas, USA

The downstream fining of fluvial sediments is a fundamental tenet of drainage systems and, for decades, has been the subject of considerable research. Most of this research has focused on variability in channel-bed material. Other sedimentological components such as channel bars and banks, however, represent distinctively different processes occurring at various flow magnitudes and durations and thus provide an opportunity to examine a more comprehensive set of controls on the larger fluvial system. This study analyses downstream patterns of sediment size and composition for channel-bed material, bars, and banks in the Llano River watershed (11,568 km²) in central Texas, USA.Fluvial deposits in the study area were characterized through field, laboratory, and statistical analyses and standard sedimentary indices (d₁₆, d₅₀, d₈₄, sorting) were computed. Two hundred thirty-eight sediment samples were collected at 15 sites along the main-stem channel with sampling occurring at the low-flow channel (thalweg), lateral bars, banks, and overbank locations. Channel-bar deposits are characterized by a downstream reduction in particle size, but low-flow-channel deposits have a substantially weaker trend, a discrepancy possibly attributed to uniformity and continuity of hydraulic sorting mechanisms during moderate and high flows. Channel-bar deposits reveal an abrupt downstream reduction in gravel size in the upper watershed, which is attributed to an increase in drainage area. Further, an abrupt gravel-to-sand transition occurs immediately downstream of a distinct lithologic change from mostly carbonate rocks to igneous and metamorphic rocks. The downstream decrease in channel-bar particle size occurs despite an increasingly constricted alluvial valley, commonly associated with greater unit stream power and relatively coarse sediment. Contrasting with channel-bed material, particle size of channel banks increases downstream, which is attributed to the addition of sand-sized sediment from igneous and metamorphic rocks. The consideration of distinctive sedimentological components of a dynamic fluvial system represents a more comprehensive and nuanced study of the topic of downstream sediment trends than prior studies, which is important to a range of engineering, biological, and planning issues at the watershed scale.     

The genesis of late Quaternary caliche nodules in Mission Bay, Texas: stable isotopic compositions and palaeoenvironmental interpretation

Caliche is a fairly widespread pedogenic carbonate that commonly has been used to reconstruct palaeoclimatological conditions. Stable isotopic analyses of three types of caliche nodules from Mission Bay, Texas, provide insights into the values and limitations in palaeoenvironmental interpretations. Soft incipient nodules (type I) and partially lithified chalky nodules (type II), composed of low Mg‐calcite, are in situ pedogenic products in the late Quaternary soils; they represent young to intermediate caliche nodules with no obvious diagenesis and, with constraints, can be used to investigate palaeoenvironmental conditions. The well‐lithified hard nodules (type III) dispersed on the beach and shallow bay exhibit complex shapes, fabrics, mineralogy and geochemical compositions. They are mature nodules that have undergone substantial diagenesis and, therefore, are believed to have lost their initial environmental signatures. The incipient nodules in the presently active grey soil and the older subjacent brown soil display significantly different δ¹³C values, ?8·4 and ?4·4‰, respectively, which indicates a change in palaeovegetation from C₃/C₄ mixed to C₃‐dominated flora. The δ¹³C values probably reflect a marked climate shift from warm and dry to cool and wet conditions in the middle Holocene. However, in the same grey soil, there is a sub‐set of incipient caliche nodules with δ¹³C values around 0·1‰, which is probably due to the input of localized carbon sources in the soil (e.g. shell fragments). The occurrence of essentially identical nodules appearing from the same modern soil horizon with significantly different δ¹³C values questions the universal reliability of this type of data for palaeoenvironmental interpretation. This study demonstrates that, whereas the stable isotopic compositions of caliche nodules can be used for palaeoenvironmental reconstruction, diagenesis and the influence of localized carbonate sources in the soils could lead to erroneous interpretations.     

The Roadian Stage of the Permian and problems of its global correlation

Ammonoids, conodonts, and fusulinids from the type sections of the Roadian and contiguous stages in western Texas and adjacent areas are analyzed and partially revised. Four successive Roadian ammonoid assemblages are distinguished and correlated with conodont zones; data on their distribution are presented. Based on the results obtained, the Roadian Stage is identified in the Boreal and Tethyan regions. Boundaries of the Roadian Stage defined accurately in the type sections of Texas are hardly recognizable elsewhere. Recognition of the upper boundary is especially difficult. Occurrence of Roadian fossils means that deposits of this age are present in a sequence, but they cannot be differentiated from underlying and overlying beds. Like in the type area, the stage lower boundary based on conodonts is above the level of significant changes in marine biota within the Boreal and Tethyan realms as well. The upper boundary is not marked by noticeable biotic events either. Correlation of the Roadian deposits is imprecise because their boundaries are formally established using distribution of relatively rare conodonts.     

Discerning resuspended chlorophyll concentrations from ocean color satellite imagery

Ocean color satellite imagery has been used to detect blooms of phytoplankton for decades. A bloom in this sense is defined as a rapid increase in chlorophyll-a concentration from newly synthesized sources (primary production) within the photic zone. Chlorophyll also has the potential to enter the water column from benthic sources as a result of resuspension events. Currently available bio-optical ocean color algorithms estimate the near-surface chlorophyll concentration in the water column but cannot characterize the source. By estimating resuspension, one can isolate the proportion of the total chlorophyll present in the water column that originated from benthic sources. The increase in remote sensing reflectance (Rrs) at 670nm as measured by SeaWiFS appears as a result of an increase in suspended materials, therefore, providing an estimate of resuspension. After examining imagery in locations of variable resuspension along the Texas coast, a strong positive correlation between the Rrs(670) produced by resuspension and the ratio of resuspended chlorophyll to total water column chlorophyll was observed.     

Hydrology and plant survival in excavated depressions near an earthen dam in north-central Texas

This investigation examined plant survival and water sources for small depressions excavated to build an earthen dam and nature trail in north-central Texas, USA. These “inadvertent wetlands” occupy part of an outdoor education facility, overlying alluvial deposits of the Trinity River. A large lake behind the earthen dam strongly influences surface water and groundwater levels in the area. Excavated depressions receive direct precipitation, runoff, and groundwater inputs, losing water by seepage and evapotranspiration. Hydroperiods varied with location and water input: excavations receiving groundwater held water year round; others periodically desiccated. Groundwater-fed depressions had higher salinity; however, the highest average value (1,304 μS/cm) was within the freshwater range. A total of 66 to 75% of emergent and floating wetland species planted in three depressions survived after 2 years. The developing wetlands appear viable under hydrologic conditions typical of the study period. Ultimately, variable hydroperiods among wetlands, and water level fluctuations within individual wetlands, may foster diverse plant-species compositions. Depressed lake levels following long-term drought or increased water demands pose the greatest threat to the developing wetlands.     

Interpreting sustainable yield of an aquifer using a fuzzy framework

Reliable estimates for how much water can be safely withdrawn from aquifers without harming the environment is crucial for identifying new water supply sources and fostering sustainable growth. Methodologies to estimate groundwater availability that are rooted in science and yet accomplishable with minimal data are particularly useful for effectual aquifer management. Also, as groundwater management is increasingly becoming a participatory process, these methodologies must be transparent and easily understood by a wide range of audiences. In addition, proposed approaches must also reconcile imprecision and uncertainties arising from lack of data, differences in stakeholders’ perceptions and limitations associated with incomplete aquifer characterization. In this study, the fundamental concept of water balance is coupled with fuzzy regression to develop a scheme for assessing regional-scale groundwater availability. Using the mass-balance approach, anthropogenic water demands (municipal, industrial and agricultural) and ecological demands (baseflows to rivers) can be incorporated into the availability estimation process. The use of fuzzy regression enables the specification of decision makers’ preferences to the adopted procedure and renders the parameter estimation to be more robust in the presence of extreme values. The methodology is illustrated by using it to estimate groundwater availability in the Gulf coast aquifer, underlying Refugio County, TX, USA.     

Developing a protocol for selecting and dating sandy sites in East Central Texas: Preliminary results

Vast areas of East Central Texas are overlain by deep unconsolidated sands, previously assumed to have been formed by in situ weathering and pedoturbation of the bedrock. This hypothesis would imply that palaeoenvironmental and archaeological reconstructions are of limited value. However, recent research has hinted that some elements of the landscape may have undergone repeated phases of erosion and redeposition, suggesting firstly that a reliable record of past environmental conditions may be gleaned from these deposits, and secondly that optically stimulated luminescence (OSL) may provide the key to unlocking this record. This research examines the depositional history of sites shown to provide a reliable chronology. Dates from these sites show that aeolian deposition occurred in East Central Texas at a number of times during the Holocene and Late Glacial, whilst three episodes of gullying occurred between approximately 123,000 and 44,000 years ago. The concordance of some of these results indicates that some phases of deposition may be regional.     

Bayesian analysis of groundwater quality in a semi-arid coastal county of south Texas

Bayesian frameworks for comparing water quality information to a pre-specified standard or goal and comparing water quality characteristics among two different entities are presented and illustrated using chloride and total dissolved solids (TDS) measurements obtained in the shallower Chicot and the deeper Evangeline formations of the Gulf coast aquifer underlying Refugio County, TX. The Bayesian approach seeks to present evidence in favor of the competing hypotheses which are weighed equally and unlike classical statistics do not make a decision in favor of one hypothesis. When comparing water quality information to a specified goal, the Bayesian approach addresses the more practical question—given all the information, what is the probability of meeting the goal? Similarly, when comparing the water quality between two entities, the approach simply emphasizes the nature and extent of differences and as such is better suited for evaluative studies. Bayesian analysis indicated that average chloride concentrations in the Evangeline formation was 1.65 times the concentrations in the Chicot formation while the corresponding TDS concentration ratio was close to unity. The probability of identifying water with TDS ≤1,000 g/m³ was extremely low, especially in the more prolific Evangeline formation. The probability of groundwater supplies with mean chloride concentrations ≤500 g/m³ was relatively high in the Chicot formation but very low in the Evangeline formation indicating the possible need for blending groundwater with other sources to meet municipal water quality goals.     

Estimation of the size of molluscan larval settlement using the death assemblage

The death assemblage is an important source of information about temporal variability in community composition. The living community and the short-term death assemblage have been studied at a sandy-bottom station in the Laguna Madre, Texas. Abundance peaks of living species are usually followed by long-term abundance increases of the same species in the death assemblage. This phenomenon provides a tool for investigating between-sampling-occasion events in the preservable component of the living community. Given a six-week sampling regimen, approximately 90% of all individuals settle, live and die during the period between consecutive sampling occasions and are not collected alive. Thus, larval settlements are consistently underestimated by about 90% from data on the living community. Comparisons of year-to-year variability in settlement and survivorship of settled individuals in the youngest age classes may be considerably in error. Better estimations of actual settlement and survivorship can be made from the death assemblage provided that the rate of taphonomic loss can be quantified. The rate of taphonomic loss can be expressed as the species' half-life, the time required for the destruction of 50% of the individuals that were added to the death assemblage following settlement. Half-lives for the smallest size classes in the death assemblage at this site are about 100 days.     

Hydrocarbon source rock variability within the Austin Chalk and Eagle Ford Shale (Upper Cretaceous), East Texas, U.S.A.

The Austin Chalk and Eagle Ford Shale are Upper Cretaceous deposits that extend across Texas from the northeast to southwest. These formations contain organic carbon enriched mudstones and chalks that were deposited during transgressions of the Cretaceous epeiric sea in North America. Recent workers in petroleum geochemistry have demonstrated that these organic enriched rocks possessed attributes common to oil source rocks. The present study of these Austin Chalk and Eagle Ford Shale rocks is from the perspective of organic petrology, and it augments the earlier geochemical work that documented source variability within units of these formations. As with the earlier work, the results of this study show that both formations contain intervals that are, when mature, capable of generating commercial quantities of liquid hydrocarbons. However, this work further revealed that Eagle Ford rocks not only exhibit greater or ganic carbon contents, but also have greater quantities of oil-prone kerogen (fluorescent amorphinite and exinite) when compared with rocks from the Austin Chalk. These source rock differences relate to levels or degrees of organic preservation. Dysaerobic to oxic depositional settings seem to be more characteristic of the Austin Chalk than of the Eagle Ford Shale. Such oxic environments do not consistently favor the preservation of organic matter. Usually, well-preserved kerogen forms under more anoxic conditions, such as those that occurred during deposition of some Eagle Ford units. These anoxic conditions suggest that the geographically more extensive Eagle Ford Shale is a more important source for oil than is the Austin Chalk.