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Adrián Cardil; Santiago Monedero; Gavin Schag; Sergio De-Miguel; Mario Tapia; Cathelijne R. Stoof; Carlos A. Silva; Midhun Mohan; Alba Cardil; Joaquin Ramirez. Fire behavior modeling for operational decision-making. Current Opinion in Environmental Science & Health 2021, 23, 100291 .
AMA StyleAdrián Cardil, Santiago Monedero, Gavin Schag, Sergio De-Miguel, Mario Tapia, Cathelijne R. Stoof, Carlos A. Silva, Midhun Mohan, Alba Cardil, Joaquin Ramirez. Fire behavior modeling for operational decision-making. Current Opinion in Environmental Science & Health. 2021; 23 ():100291.
Chicago/Turabian StyleAdrián Cardil; Santiago Monedero; Gavin Schag; Sergio De-Miguel; Mario Tapia; Cathelijne R. Stoof; Carlos A. Silva; Midhun Mohan; Alba Cardil; Joaquin Ramirez. 2021. "Fire behavior modeling for operational decision-making." Current Opinion in Environmental Science & Health 23, no. : 100291.
The knowledge about nutrient dynamics in the soil is pivotal for sustainable agriculture. A comprehensive research trial can retort unanswered questions. Dynamics of nutrients sourced from organic amendment types (chicken manure, dairy manure, and MilorganiteTM) applied at different rates (0, 168, 336, 672 kg total N/ha) were monitored within and below the rootzone of collard greens cultivated on a sandy loam soil in Prairie View, TX, USA. Macro- and micronutrients (e.g., TN: total nitrogen, P: phosphorous, K: potassium, Na: sodium, Ca: calcium, Mg: magnesium, B: boron, Cu: copper, Fe: iron, and Zn: zinc) were analyzed from soil solution samples collected during six sampling periods from within and below the rootzone. As hypothesized, the organic amendment types and rates significantly (p< 0.05 and/or 0.01) affected nutrient dynamics within and below the crop rootzone. Chicken manure released significantly more TN, P, K, Na, Ca, Mg, B, Cu, and Fe than the other two amendments. The application of chicken manure and MilorganiteTM resulted in higher below-the-rootzone leachate concentration of TN, Na, Mg, and Ca than in the leachates of dairy manure. Dairy manure treatments had the lowest concentrations of TN, Ca, and Mg; whereas, MilorganiteTM had the lowest concentrations of P, K, Na, B, and Cu in the collected leachates. The higher level of P (i.e., 4% in MilorganiteTM as compared to 2 and 0.5% in chicken and dairy manures, respectively, might have reduced the formation of Vesicular-Arbuscular (VA) mycorrhizae—a fungus with the ability to dissolve the soil P, resulting in slow release of P from MilorganiteTM treatment than from the other two treatments. Patterns of nutrient dynamics varied with rain and irrigation events under the effects of the soil water and time lapse of the amendment applications’ rates and types. All the macronutrients were present within the rootzone and leached below the rootzone, except Na. The dynamic of nutrients was element-specific and was influenced by the amendments’ type and application rate.
Ripendra Awal; Almoutaz Hassan; Farhat Abbas; Ali Fares; Haimanote Bayabil; Ram Ray; Selamawit Woldesenbet. Patterns of Nutrient Dynamics within and below the Rootzone of Collard Greens Grown under Different Organic Amendment Types and Rates. Sustainability 2021, 13, 6857 .
AMA StyleRipendra Awal, Almoutaz Hassan, Farhat Abbas, Ali Fares, Haimanote Bayabil, Ram Ray, Selamawit Woldesenbet. Patterns of Nutrient Dynamics within and below the Rootzone of Collard Greens Grown under Different Organic Amendment Types and Rates. Sustainability. 2021; 13 (12):6857.
Chicago/Turabian StyleRipendra Awal; Almoutaz Hassan; Farhat Abbas; Ali Fares; Haimanote Bayabil; Ram Ray; Selamawit Woldesenbet. 2021. "Patterns of Nutrient Dynamics within and below the Rootzone of Collard Greens Grown under Different Organic Amendment Types and Rates." Sustainability 13, no. 12: 6857.
Climate change is projected to have a global impact that affect food production and security. The objectives of this study were to determine the potential impact of climate change on sorghum yield for rainfed production systems and to evaluate the potential of irrigation and shifting planting dates as adaptation options for two major sorghum production regions in Ethiopia. The Decision Support System for Agrotechnology Transfer (DSSAT) Cropping System Model (CSM)-CERES-Sorghum model was used to simulate the impact of climate change on sorghum yield for two Representative Concentration Pathways (RCPs; RCP 4.5 and RCP 8.5) and for three future periods including the 2025s (2010–2039), 2055s (2040–2069), and 2085s (2070–2099). The Agricultural Model Improvement and Inter-comparison Project (AgMIP) framework was used to select five representative GCMs for hot/dry, cool/dry, middle, hot/wet, and cool/wet climate scenarios. Two climate change adaptation practices including supplemental irrigation at two levels (deficit and full) to the current rainfed production system and shifting planting dates were evaluated. The CSM-CERES-Sorghum model was calibrated and evaluated using eight years of experimental data from Meisso, eastern Ethiopia. The model was then run for Kobo and Meisso under different climate change and crop management scenarios. Based on model evaluation results, the model performed well for simulating sorghum yield (R2 = 0.99), anthesis (R2 = 0.86, RMSE = 1.3), and maturity (R2 = 0.79, RMSE = 4.4). The results showed that the average temperature for Kobo and Meisso is expected to increase by up to 6 °C under RCP8.5 in 2085. For the rainfed production systems without adaptation practices, drought stress is projected to intensify during anthesis, which was reflected by projected yield reductions by up 2 t ha−1 for the two sites. Full irrigation was effective in reducing moisture stress and, thereby, increasing sorghum yield by up to 3 t ha−1 for Kobo and 2 t ha−1 for Meisso. On average, full irrigation resulted in a 1 t ha−1 yield increase compared with deficit irrigation. Early planting dates also resulted in an increase in yield compared to the baseline planting dates, especially when combined with supplemental irrigation, although late planting was consistently disadvantageous even with supplemental irrigation. This study highlighted that the CSM-CERES-Sorghum model can be effectively used to simulate climate change effects on sorghum yield and evaluate different climate change adaptation practices. The outcomes of this study can also help to implement management decisions towards climate change adaptation for the current subsistence and fragile rainfed crop production system in Ethiopia and similar ecoregions across the globe.
Fikadu Getachew; Haimanote K. Bayabil; Gerrit Hoogenboom; Fitsum T. Teshome; Eshetu Zewdu. Irrigation and shifting planting date as climate change adaptation strategies for sorghum. Agricultural Water Management 2021, 255, 106988 .
AMA StyleFikadu Getachew, Haimanote K. Bayabil, Gerrit Hoogenboom, Fitsum T. Teshome, Eshetu Zewdu. Irrigation and shifting planting date as climate change adaptation strategies for sorghum. Agricultural Water Management. 2021; 255 ():106988.
Chicago/Turabian StyleFikadu Getachew; Haimanote K. Bayabil; Gerrit Hoogenboom; Fitsum T. Teshome; Eshetu Zewdu. 2021. "Irrigation and shifting planting date as climate change adaptation strategies for sorghum." Agricultural Water Management 255, no. : 106988.
La papaya es un importante cultivo frutícola que se cultiva en el sur de Florida con un área estimada de 356 acres. Este documento se centra en las técnicas de programación de riego basadas en ET para la papaya en las condiciones de Florida. Written by Haimanote K. Bayabil, Jonathan H. Crane, Kati W. Migliaccio, Yuncong Li, Fredy Ballen, and Sandra Guzmán, and published by the UF/IFAS Department of Agricultural and Biological Engineering, November 2020.
Haimanote K. Bayabil; Jonathan H. Crane; Kati W. Migliaccio; Yuncong Li; Fredy Ballen; Sandra Guzmán. Programación de Riego Basado en el Método de Evapotranspiración Para Papaya (Carica papaya) en Florida. EDIS 2020, 2020, 1 .
AMA StyleHaimanote K. Bayabil, Jonathan H. Crane, Kati W. Migliaccio, Yuncong Li, Fredy Ballen, Sandra Guzmán. Programación de Riego Basado en el Método de Evapotranspiración Para Papaya (Carica papaya) en Florida. EDIS. 2020; 2020 (6):1.
Chicago/Turabian StyleHaimanote K. Bayabil; Jonathan H. Crane; Kati W. Migliaccio; Yuncong Li; Fredy Ballen; Sandra Guzmán. 2020. "Programación de Riego Basado en el Método de Evapotranspiración Para Papaya (Carica papaya) en Florida." EDIS 2020, no. 6: 1.
Los recursos de agua potable están escaseando debido a aumentos en problación y aumentos en la demanda de agua, comida y energía. El estado de Florida proyecta añadir 6 millones de habitantes para el 2030 (Royer and Wang 2017). Además, eventos extremos del tiempo (p.e. inundaciones y sequías) ya son un fenómeno común. Por lo tanto a medida que el agua potable escasea y las sequias son frecuentes hay más necesidad de ser eficientes en el uso de recursos hidraulicos. Han habido importantes adelantos en tecnologías de regadíos (p.e. válvulas eléctricas, controles inteligentes, sensores de humedad de suelos, etc.) que ahorran agua (Dukes 2012). Sin embargo, la efectividad de estas tecnologías depende de varios factores como el diseño de sistemas de regadío. Diseñar equipos y sistemas de regadío eficientes no sólo ahorran dinero pero también ahorran agua. This is a Spanish language translation of: Bayabil, Haimanote, Kati Migliaccio, Michael Dukes, and Laura Vasquez. 2020. “Basic Tips for Designing Efficient Irrigation Systems”. EDIS 2020 (1). https://doi.org/10.32473/edis-ae539-2020.
Haimanote K. Bayabil; Kati W. Migliaccio; Michael Dukes; Laura Vasquez; Carlos Balerdi. Consejos Basicos para Diseñar Sistemas Eficientes de Riego. EDIS 2020, 2020, 10 -10.
AMA StyleHaimanote K. Bayabil, Kati W. Migliaccio, Michael Dukes, Laura Vasquez, Carlos Balerdi. Consejos Basicos para Diseñar Sistemas Eficientes de Riego. EDIS. 2020; 2020 (6):10-10.
Chicago/Turabian StyleHaimanote K. Bayabil; Kati W. Migliaccio; Michael Dukes; Laura Vasquez; Carlos Balerdi. 2020. "Consejos Basicos para Diseñar Sistemas Eficientes de Riego." EDIS 2020, no. 6: 10-10.
The effects of soil data sources on the performance of hydrologic model simulations remain poorly understood compared to the effects of other data inputs. This paper investigated the effects of different soil datasets in simulating streamflow and sediment yield using the Soil and Water Assessment Tool (SWAT). Furthermore, potential improvements in watershed simulations were evaluated by integrating field measured soil parameters (user soil) with global soil datasets. Five soil datasets, namely user soil, AfSIS (Africa Soil Information Service), Food and Agriculture Organization (FAO), and two integrated soils (User-AfSIS and User-FAO) produced by assimilating the user soil with the latter two, were evaluated. The benefits of the user soil in improving streamflow simulations to better replicate observed flow were greater at daily time steps than monthly. Compared to the individual AfSIS and FAO soils, their integration with the user soil improved the daily Nash-Sutcliffe Efficiency (NSE) by 0.19 and 0.17 during model calibration, respectively. Overall, all soils performed relatively similar with monthly sediment yield simulations, which were improved when it was integrated with the user soil. Based on selected rainfall events, the watershed response time was less than 1 h, which suggests that the watershed has a quick runoff response time. This paper showed that streamflow and sediment yield simulation performances of freely available global soil datasets can be improved through integration with locally measured soil information. This study demonstrated that the availability of local soil information is critical for daily hydrologic model simulations, which is critical for planning effective soil and water management practices at plot and field scales.
Haimanote K. Bayabil; Yihun T. Dile. Improving Hydrologic Simulations of a Small Watershed through Soil Data Integration. Water 2020, 12, 2763 .
AMA StyleHaimanote K. Bayabil, Yihun T. Dile. Improving Hydrologic Simulations of a Small Watershed through Soil Data Integration. Water. 2020; 12 (10):2763.
Chicago/Turabian StyleHaimanote K. Bayabil; Yihun T. Dile. 2020. "Improving Hydrologic Simulations of a Small Watershed through Soil Data Integration." Water 12, no. 10: 2763.
Several studies have documented the multifaceted impacts of climate change and variability on agricultural and environmental sustainability, and social and economic development. Climate change and variability contribute to increased warmer conditions, increased frequency of heavy rain that accounts for an increasing proportion of total rainfall, extreme weather characterized by spatially variable cycles of drought and wetness, increased frequency of tropical storms/hurricanes, increased frequency of storm surges, and accelerated rate of sea-level rise (SLR). As SLR continues, it is expected that salinity due to saltwater intrusion (SWI) will impact soil health and agricultural production. As such, the significant threats of salinity necessitate more work to be done to better understand its impact on soil health and associated functional ecosystem processes. This is of even greater importance in areas such as South Florida where the surface and groundwater resources are hydrologically connected due to the shallow and highly permeable limestone soils. A better understanding of the impacts of salinity due to SWI on soil health is critical to design effective mitigation strategies. Healthy soil has multifaceted benefits to enhance agricultural productivity, i.e. regulates the flow of water; serves as a source and sink of nutrients; minimizes greenhouse gas emissions and provides optimal biological and chemical conditions for the transformation of nutrients into plant-available forms. Improved understanding of the processes and impacts of SWI on soil health will assist in guiding management decisions and policies to mitigate the impacts of SWI and salinity on agricultural soils. This review paper provides a comprehensive overview of the impacts of SWI and soil salinity on agricultural soil health and water quality.
Haimanote K. Bayabil; Yuncong Li; Zhaohui Tong; Bin Gao. Potential management practices of saltwater intrusion impacts on soil health and water quality: a review. Journal of Water and Climate Change 2020, 12, 1327 -1343.
AMA StyleHaimanote K. Bayabil, Yuncong Li, Zhaohui Tong, Bin Gao. Potential management practices of saltwater intrusion impacts on soil health and water quality: a review. Journal of Water and Climate Change. 2020; 12 (5):1327-1343.
Chicago/Turabian StyleHaimanote K. Bayabil; Yuncong Li; Zhaohui Tong; Bin Gao. 2020. "Potential management practices of saltwater intrusion impacts on soil health and water quality: a review." Journal of Water and Climate Change 12, no. 5: 1327-1343.
Florida's tropical and subtropical fruit crop industries use various irrigation systems, including high-volume systems designed for irrigation and freeze protection, drip systems for herbaceous fruit crops (papaya, banana), and microsprinkler types, mainly for irrigation and fertigation. There continues to be a steady stream of potential tropical and subtropical fruit producers in Florida, many with little to no knowledge of the various types or purposes of various irrigation system that have been used successfully for the past 60 years. This new 9-page publication of the UF/IFAS Horticultural Sciences Department includes potential producers, Extension faculty and agents, and irrigation companies. Written by Jonathan Crane, Haimanote Bayabil, Edward A. Evans, and Fredy Ballen.https://edis.ifas.ufl.edu/hs1375
Jonathan Henry Crane; Haimanote Bayabil; Edward A. Evans; Fredy Ballen. Irrigation System Descriptions for Tropical and Subtropical Fruit Crops in Florida. EDIS 2020, 2020, 1 .
AMA StyleJonathan Henry Crane, Haimanote Bayabil, Edward A. Evans, Fredy Ballen. Irrigation System Descriptions for Tropical and Subtropical Fruit Crops in Florida. EDIS. 2020; 2020 (5):1.
Chicago/Turabian StyleJonathan Henry Crane; Haimanote Bayabil; Edward A. Evans; Fredy Ballen. 2020. "Irrigation System Descriptions for Tropical and Subtropical Fruit Crops in Florida." EDIS 2020, no. 5: 1.
Cathelijne R. Stoof. Fire Effects on Soils and Hydrology. Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires 2020, 369 -372.
AMA StyleCathelijne R. Stoof. Fire Effects on Soils and Hydrology. Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires. 2020; ():369-372.
Chicago/Turabian StyleCathelijne R. Stoof. 2020. "Fire Effects on Soils and Hydrology." Encyclopedia of Wildfires and Wildland-Urban Interface (WUI) Fires , no. : 369-372.
Chemigation is a process where an irrigation system is used for transport and delivery of agrochemicals, generally fertilizers and pesticides, to a crop (Haman and Zazueta, 2017). Drip or micro-sprinkler irrigation systems are often used in chemigation. If the irrigation is properly plumed and chemigation properly implemented, chemigation can help growers reduce chemical usage and costs as it is applied using existing irrigation distribution infrastructure. However, the irrigation system must first be outfitted with properly designed injection and safety equipment. In addition, it is important that the irrigation system is built to allow the injection of chemicals or fertilizers at a known rate and that ensures application uniformity. Knowing the correct concentration of chemicals during chemigation is critical as some chemicals could potentially damage plants. Chemigation of chemicals/fertilizers at higher concentrations could also lead to leaching and contamination of freshwater bodies. The purpose of this document is to provide a brief overview of the regulations and some helpful tips for growers interested in chemigation.
Haimanote K. Bayabil; Kati W. Migliaccio; Jonathan H. Crane; Teresa Olczyk; Qingren Wang. Regulations and Guidelines for Chemigation. EDIS 2020, 2020, 5 -5.
AMA StyleHaimanote K. Bayabil, Kati W. Migliaccio, Jonathan H. Crane, Teresa Olczyk, Qingren Wang. Regulations and Guidelines for Chemigation. EDIS. 2020; 2020 (4):5-5.
Chicago/Turabian StyleHaimanote K. Bayabil; Kati W. Migliaccio; Jonathan H. Crane; Teresa Olczyk; Qingren Wang. 2020. "Regulations and Guidelines for Chemigation." EDIS 2020, no. 4: 5-5.
Climate change is expected to alter fire regimes but also rainfall patterns. Fire is a natural process that removes vegetation and may affect soil properties, resulting in changes in overland flow and streamflow generation. Some fires cause erosion and may even cause destructive debris flow and other events, which can not only threaten lives and property but also leave lasting imprints in landscapes. The geomorphological response after fire events is a complex function of pre-fire landscape and vegetation properties, fire behavior and effects, and post-fire rainfall timing, duration and intensity. In this talk, I highlight these processes using examples of past events, and explore geomorphological response to fires in a future where both fire and rainfall may be be rather different.
Cathelijne Stoof. Fire effects on geomorphology: what can we expect with climate change? 2020, 1 .
AMA StyleCathelijne Stoof. Fire effects on geomorphology: what can we expect with climate change? . 2020; ():1.
Chicago/Turabian StyleCathelijne Stoof. 2020. "Fire effects on geomorphology: what can we expect with climate change?" , no. : 1.
Indoor vertical farming has been gaining increased popularity worldwide as a method of addressing food security while satisfying sustainability needs. This fact sheet written by and published by the UF/IFAS provides a comprehensive summary of the current status of indoor vertical farming in the United States and globally, commercial derivatives, major sustainability benefits and limitations and challenges. Learn about the limitations and challenges of the industry as well as the potential benefits both for food security and resource sustainability.https://edis.ifas.ufl.edu/fr429
Jiangxiao Qiu; Haimanote Bayabil; Yuncong Li. Indoor Vertical Farming Systems for Food Security and Resource Sustainability. EDIS 2020, 2020, 5 -5.
AMA StyleJiangxiao Qiu, Haimanote Bayabil, Yuncong Li. Indoor Vertical Farming Systems for Food Security and Resource Sustainability. EDIS. 2020; 2020 (2):5-5.
Chicago/Turabian StyleJiangxiao Qiu; Haimanote Bayabil; Yuncong Li. 2020. "Indoor Vertical Farming Systems for Food Security and Resource Sustainability." EDIS 2020, no. 2: 5-5.
Three irrigation scheduling methods (set schedule, ET-based, and tensiometer-based) were tested for papaya production in south Florida. ET-based irrigation scheduling was found to conserve water effectively. This 6-page document primarily focuses on the ET-based irrigation scheduling techniques for papaya under Florida conditions. Written by Haimanote K. Bayabil, Jonathan H. Crane, Kati W. Migliaccio, Yuncong Li, and Fredy Ballen, and published by the UF/IFAS Department of Agricultural and Biological Engineering, March 2020. https://edis.ifas.ufl.edu/ae540
Haimanote Bayabil; Jonathan Crane; Kati W. Migliaccio; Yuncong Li; Fredy Ballen. ET-Based Irrigation Scheduling for Papaya (Carica papaya) in Florida. EDIS 2020, 2020, 1 .
AMA StyleHaimanote Bayabil, Jonathan Crane, Kati W. Migliaccio, Yuncong Li, Fredy Ballen. ET-Based Irrigation Scheduling for Papaya (Carica papaya) in Florida. EDIS. 2020; 2020 (2):1.
Chicago/Turabian StyleHaimanote Bayabil; Jonathan Crane; Kati W. Migliaccio; Yuncong Li; Fredy Ballen. 2020. "ET-Based Irrigation Scheduling for Papaya (Carica papaya) in Florida." EDIS 2020, no. 2: 1.
Land degradation in developing countries is exacerbating hardpan development that causes the formation of perched water table, which in turn results in increased runoff and erosion. To reduce overland flow and erosion, percolation through the hardpan needs to be improved. One successful way to achieve this is ripping off the hardpan and plausibly liming. However, in the highlands of Ethiopia, there is little information available on these two techniques. The objectives of this study were, therefore, to determine the effects of ripping off degraded soils on runoff and erosion rates and whether liming would improve the effectiveness of ripping. A field study was conducted in the Anjeni watershed. Thirty‐two experimental runoff plots were installed across the watershed. Conventional tillage at 15 cm depth and ripping to 30, 45 and 60 cm depths were applied with and without lime amendments. Results showed that ripping to 60 cm depth resulted in a significant reduction of runoff. However, liming increased runoff response, on average by 10%. In contrast to the reduction in runoff amounts, an increase in ripping depth increased the amount of soil loss especially during the first storms at the beginning of the monsoon rainy season. Liming significantly decreased soil loss by up to 35%. Although plots with deep ripping plus liming had greater runoff production than other plots, soil loss was less. Overall, the findings suggest that deep ripping has promise but more research is needed before widely implemented. This article is protected by copyright. All rights reserved.
Tigist Y. Tebebu; Haimanote K. Bayabil; Tammo S. Steenhuis. Can degraded soils be improved by ripping through the hardpan and liming? A field experiment in the humid Ethiopian Highlands. Land Degradation & Development 2020, 31, 2047 -2059.
AMA StyleTigist Y. Tebebu, Haimanote K. Bayabil, Tammo S. Steenhuis. Can degraded soils be improved by ripping through the hardpan and liming? A field experiment in the humid Ethiopian Highlands. Land Degradation & Development. 2020; 31 (15):2047-2059.
Chicago/Turabian StyleTigist Y. Tebebu; Haimanote K. Bayabil; Tammo S. Steenhuis. 2020. "Can degraded soils be improved by ripping through the hardpan and liming? A field experiment in the humid Ethiopian Highlands." Land Degradation & Development 31, no. 15: 2047-2059.
As freshwater resources become increasingly scarce and droughts become more frequent, there is a need for efficient use of water resources. Designing efficient irrigation systems and equipment will not only save money but also conserve water. This 10-page fact sheet discusses factors to consider when designing irrigation systems. Written by Haimanote K. Bayabil, Kati W. Migliaccio, Michael Dukes, and Laura Vasquez, and published by the UF/IFAS Department of Agricultural and Biological Engineering, February 2020.https://edis.ifas.ufl.edu/ae539
Haimanote Bayabil; Kati W. Migliaccio; Michael D. Dukes; Laura Vasquez. Basic Tips for Designing Efficient Irrigation Systems. EDIS 2020, 2020, 1 .
AMA StyleHaimanote Bayabil, Kati W. Migliaccio, Michael D. Dukes, Laura Vasquez. Basic Tips for Designing Efficient Irrigation Systems. EDIS. 2020; 2020 (1):1.
Chicago/Turabian StyleHaimanote Bayabil; Kati W. Migliaccio; Michael D. Dukes; Laura Vasquez. 2020. "Basic Tips for Designing Efficient Irrigation Systems." EDIS 2020, no. 1: 1.
This article is part of a series on ET-based irrigation scheduling for agriculture. The rest of the series can be found at http://edis.ifas.ufl.edu/topic_series_ET-based_irrigation_scheduling_for_agriculture.
Isaya Kisekka; Kati W. Migliaccio; Michael D. Dukes; Bruce Schaffer; Jonathan Crane; Kelly Morgan; Haimanote Bayabil; Sandra M. Guzman. Evapotranspiration-Based Irrigation for Agriculture: Sources of Evapotranspiration Data for Irrigation Scheduling in Florida. EDIS 2020, 2020, 1 .
AMA StyleIsaya Kisekka, Kati W. Migliaccio, Michael D. Dukes, Bruce Schaffer, Jonathan Crane, Kelly Morgan, Haimanote Bayabil, Sandra M. Guzman. Evapotranspiration-Based Irrigation for Agriculture: Sources of Evapotranspiration Data for Irrigation Scheduling in Florida. EDIS. 2020; 2020 (1):1.
Chicago/Turabian StyleIsaya Kisekka; Kati W. Migliaccio; Michael D. Dukes; Bruce Schaffer; Jonathan Crane; Kelly Morgan; Haimanote Bayabil; Sandra M. Guzman. 2020. "Evapotranspiration-Based Irrigation for Agriculture: Sources of Evapotranspiration Data for Irrigation Scheduling in Florida." EDIS 2020, no. 1: 1.
Peter Moore; Strategic Communication; Bethany Hannah; Jasper De Vries; Marijn Poortvliet; Ron Steffens; Cathelijne R. Stoof; Wass; Soil Geography And Landscape. Gestión de Incendios Forestales durante COVID-19. Informe 1, Revisión de materiales. Gestión de Incendios Forestales durante COVID-19. Informe 1, Revisión de materiales 2020, 1 .
AMA StylePeter Moore, Strategic Communication, Bethany Hannah, Jasper De Vries, Marijn Poortvliet, Ron Steffens, Cathelijne R. Stoof, Wass, Soil Geography And Landscape. Gestión de Incendios Forestales durante COVID-19. Informe 1, Revisión de materiales. Gestión de Incendios Forestales durante COVID-19. Informe 1, Revisión de materiales. 2020; ():1.
Chicago/Turabian StylePeter Moore; Strategic Communication; Bethany Hannah; Jasper De Vries; Marijn Poortvliet; Ron Steffens; Cathelijne R. Stoof; Wass; Soil Geography And Landscape. 2020. "Gestión de Incendios Forestales durante COVID-19. Informe 1, Revisión de materiales." Gestión de Incendios Forestales durante COVID-19. Informe 1, Revisión de materiales , no. : 1.
Cathelijne R. Stoof; Soil Geography And Landscape; Jasper R. De Vries; Marijn Poortvliet; Bethany Hannah; Ron Steffens; Peter Moore; Strategic Communication; Wass. Preview Brief 2: Wildland Fire Management under COVID-19, Survey Results. Preview Brief 2: Wildland Fire Management under COVID-19, Survey Results 2020, 1 .
AMA StyleCathelijne R. Stoof, Soil Geography And Landscape, Jasper R. De Vries, Marijn Poortvliet, Bethany Hannah, Ron Steffens, Peter Moore, Strategic Communication, Wass. Preview Brief 2: Wildland Fire Management under COVID-19, Survey Results. Preview Brief 2: Wildland Fire Management under COVID-19, Survey Results. 2020; ():1.
Chicago/Turabian StyleCathelijne R. Stoof; Soil Geography And Landscape; Jasper R. De Vries; Marijn Poortvliet; Bethany Hannah; Ron Steffens; Peter Moore; Strategic Communication; Wass. 2020. "Preview Brief 2: Wildland Fire Management under COVID-19, Survey Results." Preview Brief 2: Wildland Fire Management under COVID-19, Survey Results , no. : 1.
Cathelijne R. Stoof; Soil Geography And Landscape; A.J.G. Tijhuis; Guillermo Rein; Núria Prat-Guitart; Miriam Arenas Conejo; Israel Rodríguez-Giralt; Nicholas Kettridge; C-HR Organisatie- & HR-Ontwikkeling. PyroLife PhD recruitment rubric and best practices. PyroLife PhD recruitment rubric and best practices 2020, 1 .
AMA StyleCathelijne R. Stoof, Soil Geography And Landscape, A.J.G. Tijhuis, Guillermo Rein, Núria Prat-Guitart, Miriam Arenas Conejo, Israel Rodríguez-Giralt, Nicholas Kettridge, C-HR Organisatie- & HR-Ontwikkeling. PyroLife PhD recruitment rubric and best practices. PyroLife PhD recruitment rubric and best practices. 2020; ():1.
Chicago/Turabian StyleCathelijne R. Stoof; Soil Geography And Landscape; A.J.G. Tijhuis; Guillermo Rein; Núria Prat-Guitart; Miriam Arenas Conejo; Israel Rodríguez-Giralt; Nicholas Kettridge; C-HR Organisatie- & HR-Ontwikkeling. 2020. "PyroLife PhD recruitment rubric and best practices." PyroLife PhD recruitment rubric and best practices , no. : 1.
Peter Moore; Strategic Communication; Bethany Hannah; Jasper De Vries; Marijn Poortvliet; Ron Steffens; Cathelijne R. Stoof; Wass; Soil Geography And Landscape. Wildland fire management under COVID-19. Brief 1, review of materials. Wildland fire management under COVID-19. Brief 1, review of materials 2020, 1 .
AMA StylePeter Moore, Strategic Communication, Bethany Hannah, Jasper De Vries, Marijn Poortvliet, Ron Steffens, Cathelijne R. Stoof, Wass, Soil Geography And Landscape. Wildland fire management under COVID-19. Brief 1, review of materials. Wildland fire management under COVID-19. Brief 1, review of materials. 2020; ():1.
Chicago/Turabian StylePeter Moore; Strategic Communication; Bethany Hannah; Jasper De Vries; Marijn Poortvliet; Ron Steffens; Cathelijne R. Stoof; Wass; Soil Geography And Landscape. 2020. "Wildland fire management under COVID-19. Brief 1, review of materials." Wildland fire management under COVID-19. Brief 1, review of materials , no. : 1.