Your search keyword '"Einara Zahn"' showing total 12 results

1. Relaxed Eddy Accumulation Outperforms Monin‐Obukhov Flux Models Under Non‐Ideal Conditions

Author

Einara Zahn, Elie Bou‐Zeid, and Nelson Luís Dias

Subjects

eddy covariance, relaxed eddy accumulation, Monin‐Obukhov Similarity Theory, carbon dioxide fluxes, variance budget, lake evaporation, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract The Monin‐Obukhov Similarity Theory (MOST) links turbulent statistics to surface fluxes through universal functions. Here, we investigate its performance over a large lake, where none of its assumptions (flat homogeneous surface) are obviously violated. We probe the connection between the variance budget terms and departure from the nondimensional flux‐variance function for CO2, water vapor, and temperature. Our results indicate that both the variance storage and its vertical transport affect MOST, and these terms are most significant when small fluxes and near neutral conditions were prevalent. Such conditions are common over lakes and oceans, especially for CO2, underlining the limitation of using any MOST‐based methods to compute small fluxes. We further show that the relaxed eddy accumulation (REA) method is more robust and less sensitive to storage and transport, adequately reproducing the eddy‐covariance fluxes even for the smallest flux magnitudes. Therefore, we recommend REA over MOST methods for trace‐gas flux estimation.

Published

2023

2. ET Partitioning Assessment Using the TSEB Model and sUAS Information across California Central Valley Vineyards

Author

Rui Gao, Alfonso F. Torres-Rua, Hector Nieto, Einara Zahn, Lawrence Hipps, William P. Kustas, Maria Mar Alsina, Nicolas Bambach, Sebastian J. Castro, John H. Prueger, Joseph Alfieri, Lynn G. McKee, William A. White, Feng Gao, Andrew J. McElrone, Martha Anderson, Kyle Knipper, Calvin Coopmans, Ian Gowing, Nurit Agam, Luis Sanchez, and Nick Dokoozlian

Subjects

temperature separation, ET partitioning, transpiration, transpiration ratio, TSEB-PT, TSEB-2T, Science

Abstract

Evapotranspiration (ET) is a crucial part of commercial grapevine production in California, and the partitioning of this quantity allows the separate assessment of soil and vine water and energy fluxes. This partitioning has an important role in agriculture since it is related to grapevine stress, yield quality, irrigation efficiency, and growth. Satellite remote sensing-based methods provide an opportunity for ET partitioning at a subfield scale. However, medium-resolution satellite imagery from platforms such as Landsat is often insufficient for precision agricultural management at the plant scale. Small, unmanned aerial systems (sUAS) such as the AggieAir platform from Utah State University enable ET estimation and its partitioning over vineyards via the two-source energy balance (TSEB) model. This study explores the assessment of ET and ET partitioning (i.e., soil water evaporation and plant transpiration), considering three different resistance models using ground-based information and aerial high-resolution imagery from the Grape Remote sensing Atmospheric Profile and Evapotranspiration eXperiment (GRAPEX). We developed a new method for temperature partitioning that incorporated a quantile technique separation (QTS) and high-resolution sUAS information. This new method, coupled with the TSEB model (called TSEB-2TQ), improved sensible heat flux (H) estimation, regarding the bias, with around 61% and 35% compared with the H from the TSEB-PT and TSEB-2T, respectively. Comparisons among ET partitioning estimates from three different methods (Modified Relaxed Eddy Accumulation—MREA; Flux Variance Similarity—FVS; and Conditional Eddy Covariance—CEC) based on EC flux tower data show that the transpiration estimates obtained from the FVS method are statistically different from the estimates from the MREA and the CEC methods, but the transpiration from the MREA and CEC methods are statistically the same. By using the transpiration from the CEC method to compare with the transpiration modeled by different TSEB models, the TSEB-2TQ shows better agreement with the transpiration obtained via the CEC method. Additionally, the transpiration estimation from TSEB-2TQ coupled with different resistance models resulted in insignificant differences. This comparison is one of the first for evaluating ET partitioning estimation from sUAS imagery based on eddy covariance-based partitioning methods.

Published

2023

3. Evaluation of Partitioned Evaporation and Transpiration Estimates within the DisALEXI Modeling Framework over Irrigated Crops in California

Author

Kyle Knipper, Martha Anderson, Nicolas Bambach, William Kustas, Feng Gao, Einara Zahn, Christopher Hain, Andrew McElrone, Oscar Rosario Belfiore, Sebastian Castro, Maria Mar Alsina, and Sebastian Saa

Subjects

evapotranspiration, flux partitioning, ALEXI/DisALEXI, satellite remote sensing, Science

Abstract

Accurate characterization of evapotranspiration (ET) is imperative in water-limited cropping systems such as California vineyards and almond orchards. Satellite-based ET modeling techniques, including the atmosphere–land exchange inverse model (ALEXI) and associated flux disaggregation technique (DisALEXI), have proven reliable in determining field scale ET. However, validation efforts typically focus on ET and omit an evaluation of partitioned evaporation (E) and transpiration (T). ALEXI/DisALEXI is based on the two-source energy balance (TSEB) model, making it uniquely qualified to derive E and T individually. The current study evaluated E and T estimates derived using two formulations of DisALEXI; one based on Priestley-Taylor (DisALEXI-PT) and the other on Penman-Monteith (DisALEXI-PM). The modeled values were validated against partitioned fluxes derived from the conditional eddy covariance (CEC) approach using EC flux towers in three wine grape vineyards and three almond orchards for the year 2021. Modeled estimates were derived using Landsat 8 Collection 2 thermal infrared and surface reflectance imagery as well as Harmonized Landsat and Sentinel-2 surface reflectance datasets as input into DisALEXI. The results indicated that the modeled total ET fluxes were similar between the two methods, but the partitioned values diverged, with DisALEXI-PT overestimating E and slightly underestimating T when compared to CEC estimates. Conversely, DisALEXI-PM agreed better with CEC-derived E and overestimated T estimates under non-advective conditions. Compared to one another, DisALEXI-PM estimated canopy temperatures ~5 °C cooler and soil temperatures ~5 °C warmer than DisALEXI-PT, causing differences in E and T of −2.6 mm day−1 and +2.6 mm day−1, respectively. The evaluation of the iterative process required for DisALEXI indicates DisALEXI-PM ET values converge on ALEXI ET with proportionate adjustments to E and T, while DisALEXI-PT convergence is driven by adjustments to E. The analysis presented here can potentially drive improvements in the modeling framework to provide specific soil and canopy consumptive water use information in unique canopy structures, allowing for improved irrigation and water use efficiencies in these water-limited systems.

Published

2022

4. Application of a remote-sensing three-source energy balance model to improve evapotranspiration partitioning in vineyards

Author

Vicente Burchard-Levine, Héctor Nieto, William P. Kustas, Feng Gao, Joseph G. Alfieri, John H. Prueger, Lawrence E. Hipps, Nicolas Bambach-Ortiz, Andrew J. McElrone, Sebastian J. Castro, Maria Mar Alsina, Lynn G. McKee, Einara Zahn, Elie Bou-Zeid, and Nick Dokoozlian

Published

2022

5. Evaluation of Partitioned Evaporation and Transpiration Estimates within the DisALEXI Modeling Framework over Irrigated Crops in California.

Author

Kyle R. Knipper, Martha C. Anderson, Nicolas Bambach, William P. Kustas, Feng Gao 0009, Einara Zahn, Christopher Hain, Andrew J. McElrone, Oscar Rosario Belfiore, Sebastian J. Castro, Maria Mar Alsina, and Sebastian Saa

Published

2023

6. Evaluating different metrics from the thermal-based two-source energy balance model for monitoring grapevine water stress

Author

Héctor Nieto, María Mar Alsina, William P. Kustas, Omar García-Tejera, Fan Chen, Nicolas Bambach, Feng Gao, Joseph G. Alfieri, Lawrence E. Hipps, John H. Prueger, Lynn G. McKee, Einara Zahn, Elie Bou-Zeid, Andrew J. McElrone, Sebastian J. Castro, Nick Dokoozlian, National Aeronautics and Space Administration (US), Department of Agriculture (US), Agricultural Research Service (US), Conferencia de Rectores de las Universidades Españolas, Consejo Superior de Investigaciones Científicas (España), and Nieto, Héctor

Subjects

Soil Science, Agronomy and Crop Science, Water Science and Technology

Abstract

Precision irrigation management requires operational monitoring of crop water status. However, there is still some controversy on how to account for crop water stress. To address this question, several physiological, several physiological metrics have been proposed, such as the leaf/stem water potentials, stomatal conductance, or sap flow. On the other hand, thermal remote sensing has been shown to be a promising tool for efficiently evaluating crop stress at adequate spatial and temporal scales, via the Crop Water Stress Index (CWSI), one of the most common indices used for assessing plant stress. CWSI relates the actual crop evapotranspiration ET (related to the canopy radiometric temperature) to the potential ET (or minimum crop temperature). However, remotely sensed surface temperature from satellite sensors includes a mixture of plant canopy and soil/substrate temperatures, while what is required for accurate crop stress detection is more related to canopy metrics, such as transpiration, as the latter one avoids the influence of soil/substrate in determining crop water status or stress. The Two-Source Energy Balance (TSEB) model is one of the most widely used and robust evapotranspiration model for remote sensing. It has the capability of partitioning ET into the crop transpiration and soil evaporation components, which is required for accurate crop water stress estimates. This study aims at evaluating different TSEB metrics related to its retrievals of actual ET, transpiration and stomatal conductance, to track crop water stress in a vineyard in California, part of the GRAPEX experiment. Four eddy covariance towers were deployed in a Variable Rate Irrigation system in a Merlot vineyard that was subject to different stress periods. In addition, root-zone soil moisture, stomatal conductance and leaf/stem water potential were collected as proxy for in situ crop water stress. Results showed that the most robust variable for tracking water stress was the TSEB derived leaf stomatal conductance, with the strongest correlation with both the measured root-zone soil moisture and stomatal conductance gas exchange measurements. In addition, these metrics showed a better ability in tracking stress when the observations are taken early after noon., Funding and logistical support for the GRAPEX project were provided by E. & J. Gallo Winery and from the NASA Applied Sciences-Water Resources Program (Grant no. NNH17AE39I). This research was also supported in part by the U.S. Department of Agriculture, Agricultural Research Service. Open Access funding provided thanks to the CRUE-CSIC agreement with Springer Nature.

Published

2022

7. The Hydrological Urban Heat Island: Determinants of Acute and Chronic Heat Stress in Urban Streams

Author

Claire Welty, James A Smith, Elie and Bou‐Zeid, M. L. Baeck, Einara Zahn, and Stanley J. Kemp

Subjects

Hydrology, Baseflow, Ecology, Water flow, Environmental science, Hydrometeorology, STREAMS, Urban heat island, Surge, Surface runoff, Thermal pollution, Earth-Surface Processes, Water Science and Technology

Abstract

Research Impact Statement: Urbanization increases baseflow stream temperature and exacerbates stream temperature surges, creating a hydrological urban heat island. ABSTRACT: During and after rainfall events, the interaction of precipitation with hot urban pavements leads to hot runoff, and its merger with urban streams can result in an abrupt change in water temperature that can harm aquatic ecosystems. To understand this phenomenon and its relation to land cover and hydrometeorological parameters, we analyzed data spanning two years from 100 sites in the eastern United States. To identify surges, we first isolated temperature jumps of at least 0.5°C over 15 min occurring simultaneously with water flow increase. Surge magnitude was defined as the difference between peak stream temperature and baseflow temperature right before the jump. At least 10 surges were observed in 53 of the studied streams, with some surges exceeding 10°C. Our results demonstrate that the watershed developed area and vegetation fraction are the best descriptors of surge frequency (Spearman correlation of 0.76 and 0.77, respectively). On the other hand, for surge magnitude and peak temperature, the primary drivers are stream discharge and stream temperature immediately before the surge. In general, the more urbanized streams were found to be already warmer than their more “vegetated” counterparts during baseflow conditions, and were also the most affected by temperature surges. Together, these findings suggest the existence of a hydrological urban heat island, here defined as the increase in stream temperature (chronic and/or acute), caused by increased urbanization.

Published

2021

8. Impact of advection on two-source energy balance (TSEB) canopy transpiration parameterization for vineyards in the California Central Valley

Author

William P. Kustas, Hector Nieto, Omar Garcia-Tejera, Nicolas Bambach, Andrew J. McElrone, Feng Gao, Joseph G. Alfieri, Lawrence E. Hipps, John H. Prueger, Alfonso Torres-Rua, Martha C. Anderson, Kyle Knipper, Maria Mar Alsina, Lynn G. McKee, Einara Zahn, Elie Bou-Zeid, Nick Dokoozlian, E. & J. Gallo Winery, National Aeronautics and Space Administration (US), Department of Agriculture (US), and Agricultural Research Service (US)

Subjects

Soil Science, Agronomy and Crop Science, Water Science and Technology

Abstract

Water conservation efforts for California’s agricultural industry are critical to its sustainability through severe droughts like the current one and others experienced over the last two decades. This is most critical for perennial crops, such as vineyards and orchards, which are costly to plant and maintain and constitute a significant fraction of the regional water use. It is no longer feasible to access groundwater for irrigation to replace deficit surface water resources during drought due to a significant overdraft of aquifers and new regulation limiting its use. To achieve significant water savings, the actual crop water use or evapotranspiration (ET) needs to be mapped from field to regional scales on a daily basis. This can only be achieved using remote sensing-based models, particularly thermal-based energy balance models that are sensitive to deficit irrigation conditions. The two-source energy balance (TSEB) model has been successfully applied over vineyards in California, but challenges still remain. In particular, much of the irrigated cropland in the California Central Valley is affected by advection of hot dry air masses from surrounding non-irrigated areas and the TSEB model appears to need modifications to adequately estimate ET under such conditions, as well as the partitioning between evaporation and transpiration. This study investigates the application of the TSEB model, using local observations in a vineyard having significant advection. Four versions of the transpiration algorithm in TSEB are applied and evaluated with tower eddy covariance measurements spanning 4 growing seasons. The results suggest the performance of the original transpiration algorithm based on Priestley–Taylor used in TSEB is satisfactory in all but the most extreme advective conditions, while a transpiration algorithm based on Shuttleworth–Wallace with a canopy resistance formula, which relates maximum stomata conductance to vapor pressure deficit (VPD), performs well in all cases. These modifications have potential for improving regional applications of the TSEB model in support of water management in the Central Valley., Funding and logistical support for the GRAPEX project were provided by E. & J. Gallo Winery and from the NASA Applied Sciences-Water Resources Program (Grant No. NNH17AE39I). This research was also supported in part by the U.S. Department of Agriculture, Agricultural Research Service.

Published

2022

9. Experimental and Numerical Investigation of Flux Partitioning Methods for Water Vapor and Carbon Dioxide

Author

Elie Bou-Zeid, Einara Zahn, Khaled Ghannam, Marcelo Chamecki, Gabriel Katul, Christoph Thomas, and William Kustas

Abstract

The partitioning of ecosystem evapotranspiration and carbon dioxide fluxes into their plant and ground components is a critical research priority to better understand the water cycle and ecosystem function. Despite advances in different measurement techniques and partitioning models in the last decades, much is still unknown regarding the importance of different components of H2O and CO2 fluxes in ecosystems. In this work, we compare three partitioning methods that are based on analysis of conventional high frequency eddy-covariance (EC) data: the flux variance similarity method, the modified relaxed eddy accumulation methods, and the conditional eddy covariance method. First, we test these methods using fields experimental data, comparing them to other reference measurements for the components fluxes (gas chambers and leaf levels measurements). Subsequently, we develop a novel approach for simulating these fluxes in large eddy simulations and apply it to further probe the performance, assumptions, and relative skill of the three methods. The findings allow us to recommend partitioning best practices for their implementation, and to develop methods for the joint analyses of the various approaches.

Published

2022

10. Flux-variance and flux-gradient relationships in the roughness sublayer over the Amazon forest

Author

Marta Sá, Antonio O. Manzi, Matthias Sörgel, Alessandro Araújo, Ivonne Trebs, Tomas Chor, Einara Zahn, Paulo R. Teixeira, Nelson Luís Dias, and Stefan Wolff

Subjects

Atmospheric Science, Global and Planetary Change, 010504 meteorology & atmospheric sciences, Meteorology, 0208 environmental biotechnology, Eddy covariance, Scalar (physics), Forestry, 02 engineering and technology, Surface finish, Atmospheric sciences, 01 natural sciences, 020801 environmental engineering, Flux (metallurgy), Dry season, Environmental science, Agronomy and Crop Science, Temperate rainforest, Water vapor, 0105 earth and related environmental sciences, Dimensionless quantity

Abstract

The failure of the Monin–Obukhov Similarity Theory (MOST) in the roughness sublayer is a major problem for the estimation of fluxes over tall forests, whenever indirect methods that rely on MOST, such as flux-gradient or the variance method, are involved. While much research focuses on micrometeorological measurements over temperate-climate forests, very few studies deal with such measurements over tropical forests. In this paper, we show evidence that some similarity functions over the Amazon forest are somewhat different from temperate forests. Comparison of the nondimensional scalar gradients canonical values for the inertial sublayer with our measurements in the roughness sublayer showed smaller deviations than what is usually reported for temperate forests. Although the fluxes of water vapor and CO2 derived from mean profiles show considerable scatter when compared with the eddy covariance measurements, using calibrated dimensionless gradients it is possible to estimate their mean daily cycle during the period of measurement (36 days in May and June, transition between rainy and dry season). Moreover, since mean ozone profiles were available, although without the corresponding eddy covariance measurements, mean daily ozone fluxes were calculated with the flux-gradient method, yielding a nighttime value of −0.05 and a daily peak of −0.45 μg m−2 s−1 (−1.04 and −9.37 nmol m−2 s−1, respectively). These values are comparable to previously measured fluxes in the literature for the Amazon forest.

Published

2017

11. Scalar turbulent behavior in the roughness sublayer of an Amazonian forest

Author

Antonio O. Manzi, Matthias Sörgel, Leonardo D. A. Sá, Alessandro Araújo, Einara Zahn, Nelson Luís Dias, Ivonne Trebs, Stefan Wolff, EINARA ZAHN, UFPR, NELSON L. DIAS, UFPR, ALESSANDRO CARIOCA DE ARAUJO, CPATU, LEONARDO SÁ, INPE, MATTHIAS SÖERGE, Max Planck Institute for Chemistry, IVONNE TREBS, ERIN, STEFAN WOLFF, Max Planck Institute for Chemistry, ANTÔNIO MANZI, INPA., Einara Zahn, Graduate Program in Environmental Engineering (PPGEA), UFPR, Nelson L. Dias, UFPR, Leonardo D. A. Sá, INPE, Matthias Sörgel, Max Planck Institute for Chemistry, Ivonne Trebs, Environmental Research and Innovation (ERIN), Stefan Wolff, Max Planck Institute for Chemistry, and Antônio Manzi, INPE.

Subjects

Physics, Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, Turbulence, Floresta Tropical, Scalar (physics), Dissipation, Atmospheric sciences, 01 natural sciences, lcsh:QC1-999, 010305 fluids & plasmas, lcsh:Chemistry, Physics::Fluid Dynamics, lcsh:QD1-999, Climatologia, 0103 physical sciences, Turbulence kinetic energy, Range (statistics), Virtual temperature, lcsh:Physics, Zenith, 0105 earth and related environmental sciences, Dimensionless quantity

Abstract

An important current problem in micrometeorology is the characterization of turbulence in the roughness sublayer (RSL), where most of the measurements above tall forests are made. There, scalar turbulent fluctuations display significant departures from the predictions of Monin?Obukhov similarity theory (MOST). In this work, we analyze turbulence data of virtual temperature, carbon dioxide, and water vapor in the RSL above an Amazonian forest (with a canopy height of 40 m), measured at 39.4 and 81.6 m above the ground under unstable conditions. We found that dimensionless statistics related to the rate of dissipation of turbulence kinetic energy (TKE) and the scalar variance display significant departures from MOST as expected, whereas the vertical velocity variance follows MOST much more closely. Much better agreement between the dimensionless statistics with the Obukhov similarity variable, however, was found for the subset of measurements made at a low zenith angle Z, in the range 0°

Published

2016

12. CICLAR: Modelo 0D para Dinâmica de Carbono em Lagos e Reservatórios

Author

João Furtado Resende, Cristovão Vicente Scapulatempo Fernandes, Julio Werner Yoshioka Bernardo, Michael Mannich, Tobias Bleninger, and Einara Zahn

Subjects

Environmental science, Aquatic Science, Oceanography, Earth-Surface Processes, Water Science and Technology

Published

2015