Effects of Water-Table Configuration on the Planetary Boundary Layer over the San Joaquin River Watershed, California

Gilbert, James; Maxwell, R. M.; Gochis, David

doi:10.1175/jhm-d-16-0134.1

Cited by 25 publications

(25 citation statements)

References 61 publications

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“…Recharge in premodern floodplains was likely slower than recharge on cultivated fields, allowing water to reach thermal equilibrium with the surroundings at temperatures closer to the mean annual air temperature. The extensive irrigation with river water also impacts air temperatures through the irrigation cooling effect (Kueppers, Snyder, & Sloan, ), the height of the planetary boundary layer (Gilbert, Maxwell, & Gochis, ), and precipitation patterns (Yang et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…A large range of noble gas recharge temperatures (σ = 3.1°C) is with river water also impacts air temperatures through the irrigation cooling effect (Kueppers, Snyder, & Sloan, 2007), the height of the planetary boundary layer (Gilbert, Maxwell, & Gochis, 2017), and precipitation patterns (Yang et al, 2017). Fossil (Pleistocene) groundwater has mostly recharged as local precipitation because flow paths from the foothills to the discharge areas near the valley centre are naturally longer (Izbicki, Radyk, & Michel, 2000 Local precipitation comprises 55 ± 4% of modern groundwater in the San Joaquin Valley.…”

Section: Discussionmentioning

confidence: 99%

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Importance of river water recharge to the San Joaquin Valley groundwater system

Visser

Moran

Singleton

et al. 2018

Hydrological Processes

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Groundwater is not a sustainable resource, unless abstraction is balanced by recharge. Identifying the sources of recharge in a groundwater basin is critical for sustainable groundwater management. We studied the importance of river water recharge to groundwater in the south‐eastern San Joaquin Valley (24,000 km2, population 4 million). We combined dissolved noble gas concentrations, stable isotopes, tritium, and carbon‐14 analyses to analyse the sources, mechanisms, and timescales of groundwater recharge. Area‐representative groundwater sampling and numerical model input data enabled a stable isotope mass balance and quantitative estimates of river and local recharge. River recharge, identified by a lighter stable isotope signature, represents 47 ± 4% of modern groundwater in the San Joaquin Valley (recharged after 1950) but only 26 ± 4% of premodern groundwater (recharged before 1950). This implies that the importance of river water recharge in the San Joaquin valley has nearly doubled and is likely the result of a 40% increase in total recharge, caused by river water irrigation return flows and increased stream depletion and river recharge due to groundwater pumping. Compared with the large and long‐duration capacity for water storage in the subsurface, storage of water in rivers is limited in time and volume, as evidenced by cold river recharge temperatures resulting from fast infiltration and recharge. Groundwater banking of seasonal surface water flows and expansion of managed aquifer recharge practices therefore appear to be a natural and promising method for increasing the resilience of the San Joaquin Valley water supply system.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Importance of river water recharge to the San Joaquin Valley groundwater system

Visser

Moran

Singleton

et al. 2018

Hydrological Processes

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“…Szilagyi et al () further confirmed the link between groundwater and ET in Nebraska through observational data. In turn, these impacts may propagate into the atmospheric boundary layer, affecting the planetary boundary layer height, air temperature, convective available potential energy, and convection precipitation (e.g., Gilbert et al, ; Keune et al, ; Maxwell et al, ; Rahman et al, ; Rihani et al, ). A growing body of literature also suggests that lateral subsurface flow can substantially enhance the T / ET ratio (Fang et al, ; Maxwell & Condon, ), and this effect becomes slightly more significant for higher model resolutions (Shrestha et al, ).…”

Section: Introductionmentioning

confidence: 99%

Why Do Large‐Scale Land Surface Models Produce a Low Ratio of Transpiration to Evapotranspiration?

et al. 2018

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Most land surface models (LSMs) used in Earth System Models produce a lower ratio of transpiration (T) to evapotranspiration (ET) than field observations, degrading the credibility of Earth System Model‐projected ecosystem responses and feedbacks to climate change. To interpret this model deficiency, we conducted a pair of model experiments using a three‐dimensional, process‐based ecohydrological model in a subhumid, mountainous catchment. One experiment (CTRL) describes lateral water flow, topographic shading, leaf dynamics, and water vapor diffusion in the soil, while the other (LSM like) does not explicitly describe these processes to mimic a conventional LSM using artificially flattened terrain. Averaged over the catchment, CTRL produced a higher T/ET ratio (72%) than LSM like (55%) and agreed better with an independent estimate (79.79 ± 27%) based on rainfall and stream water isotopes. To discern the exact causes, we conducted additional model experiments, each reverting only one process described in CTRL to that of LSM like. These experiments revealed that the enhanced T/ET ratio was mostly caused by lateral water flow and water vapor diffusion within the soil. In particular, terrain‐driven lateral water flows spread out soil moisture to a wider range along hillslopes with an optimum subrange from the middle to upper slopes, where evaporation (E) was more suppressed by the drier surface than T due to plant uptake of deep soil water, thereby enhancing T/ET. A more elaborate representation of water vapor diffusion from a dynamically changing evaporating surface to the height of the surface roughness length reduced E and increased the T/ET ratio.

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“…Compared to atmospheric models routinely used for weather prediction, these models have a more detailed representation of subsurface-land surface physical processes with an explicit consideration of groundwater-surface water interactions. A growing body of literature emphasizes their potential for improving our understanding of the connections between groundwater and atmospheric processes (Gilbert et al, 2017;Keune et al, 2016Keune et al, , 2018Rahman et al, 2015). To date, only very few studies assessed the impact of such improved subsurface physics on the skills of atmospheric predictions (e.g., Larsen, Christensen, et al, 2016a;Larsen, Rasmussen et al, 2016b).…”

Section: Introductionmentioning

confidence: 99%

Quantifying the Impact of Subsurface‐Land Surface Physical Processes on the Predictive Skill of Subseasonal Mesoscale Atmospheric Simulations

et al. 2018

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Integrated terrestrial system modeling platforms, which simulate the 3‐D flow of water both in the subsurface and the atmosphere, are expected to improve the realism of predictions through a more detailed physics‐based representation of hydrometeorological processes and feedbacks. We test this expectation by evaluating simulation results from different configurations of an atmospheric model with increasing complexity in the representation of land surface and subsurface physical processes. The evaluation is performed using observations during the (HD(CP)2) Observational Prototype Experiment field campaign in April–May 2013 over western Germany. The augmented model physics do not improve the prediction of daily cumulative precipitation and minimum temperature during this period. Moreover, a cold bias is introduced in the simulated daily maximum temperature, which decreases the performance of the atmospheric model with respect to its standard configuration. The decreased performance in the maximum temperature is traced in part to a higher simulated soil moisture, which shifts surface flux partitioning toward higher latent and lower sensible heat fluxes. The better reproduced air temperature profiles simulated by the standard atmospheric model comes, however, with an overestimated heat flux at the land surface caused by a warm bias in the simulated soil temperature. Simulated atmospheric states do not correlate significantly with differences in soil moisture and temperature; thus, different turbulent flux parameterizations dominate the propagation of the subsurface signal into the atmosphere. The strong influence of the lateral synoptic forcings on the results suggests, however, the need for further investigations encompassing different weather situations or regions with stronger land‐atmosphere coupling conditions.

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Effects of Water-Table Configuration on the Planetary Boundary Layer over the San Joaquin River Watershed, California

Cited by 25 publications

References 61 publications

Importance of river water recharge to the San Joaquin Valley groundwater system

Importance of river water recharge to the San Joaquin Valley groundwater system

Why Do Large‐Scale Land Surface Models Produce a Low Ratio of Transpiration to Evapotranspiration?

Quantifying the Impact of Subsurface‐Land Surface Physical Processes on the Predictive Skill of Subseasonal Mesoscale Atmospheric Simulations

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