Your search keyword '"Wallender, Wesley W."' showing total 6 results

1. Coastal development and precipitation drive pathogen flow from land to sea: evidence from a Toxoplasma gondii and felid host system.

Author

VanWormer, Elizabeth, Carpenter, Tim E, Singh, Purnendu, Shapiro, Karen, Wallender, Wesley W, Conrad, Patricia A, Largier, John L, Maneta, Marco P, and Mazet, Jonna AK

Subjects

Animals, Cats, Toxoplasma, Ecosystem, Rain, Fresh Water, Seawater, Environmental Monitoring, Geography, California, Oceans and Seas, Host-Parasite Interactions

Abstract

Rapidly developing coastal regions face consequences of land use and climate change including flooding and increased sediment, nutrient, and chemical runoff, but these forces may also enhance pathogen runoff, which threatens human, animal, and ecosystem health. Using the zoonotic parasite Toxoplasma gondii in California, USA as a model for coastal pathogen pollution, we examine the spatial distribution of parasite runoff and the impacts of precipitation and development on projected pathogen delivery to the ocean. Oocysts, the extremely hardy free-living environmental stage of T. gondii shed in faeces of domestic and wild felids, are carried to the ocean by freshwater runoff. Linking spatial pathogen loading and transport models, we show that watersheds with the highest levels of oocyst runoff align closely with regions of increased sentinel marine mammal T. gondii infection. These watersheds are characterized by higher levels of coastal development and larger domestic cat populations. Increases in coastal development and precipitation independently raised oocyst delivery to the ocean (average increases of 44% and 79%, respectively), but dramatically increased parasite runoff when combined (175% average increase). Anthropogenic changes in landscapes and climate can accelerate runoff of diverse pathogens from terrestrial to aquatic environments, influencing transmission to people, domestic animals, and wildlife.

Published

2016

2. Coastal development and precipitation drive pathogen flow from land to sea: evidence from a Toxoplasma gondii and felid host system

Author

VanWormer, Elizabeth, Carpenter, Tim E, Singh, Purnendu, Shapiro, Karen, Wallender, Wesley W, Conrad, Patricia A, Largier, John L, Maneta, Marco P, and Mazet, Jonna AK

Subjects

Infectious Diseases, Emerging Infectious Diseases, 2.2 Factors relating to the physical environment, Aetiology, Infection, Life on Land, Life Below Water, Animals, California, Cats, Ecosystem, Environmental Monitoring, Fresh Water, Geography, Host-Parasite Interactions, Oceans and Seas, Rain, Seawater, Toxoplasma

Abstract

Rapidly developing coastal regions face consequences of land use and climate change including flooding and increased sediment, nutrient, and chemical runoff, but these forces may also enhance pathogen runoff, which threatens human, animal, and ecosystem health. Using the zoonotic parasite Toxoplasma gondii in California, USA as a model for coastal pathogen pollution, we examine the spatial distribution of parasite runoff and the impacts of precipitation and development on projected pathogen delivery to the ocean. Oocysts, the extremely hardy free-living environmental stage of T. gondii shed in faeces of domestic and wild felids, are carried to the ocean by freshwater runoff. Linking spatial pathogen loading and transport models, we show that watersheds with the highest levels of oocyst runoff align closely with regions of increased sentinel marine mammal T. gondii infection. These watersheds are characterized by higher levels of coastal development and larger domestic cat populations. Increases in coastal development and precipitation independently raised oocyst delivery to the ocean (average increases of 44% and 79%, respectively), but dramatically increased parasite runoff when combined (175% average increase). Anthropogenic changes in landscapes and climate can accelerate runoff of diverse pathogens from terrestrial to aquatic environments, influencing transmission to people, domestic animals, and wildlife.

Published

2016

3. No-tillage and high-residue practices reduce soil water evaporation

Author

Mitchell, Jeffrey P, Singh, Purnendu N, Wallender, Wesley W, Munk, Daniel S, Wroble, Jon F, Horwath, William R, Hogan, Philip, Roy, Robert, and Hanson, Blaine R

Subjects

plant residues, Plant Science and Plant Products, crop production, crop management, agronomy, irrigation and drainage, conservation tillage, Land, Air and Water Sciences

Abstract

Reducing tillage and maintaining crop residues on the soil surface could improve the water use efficiency of California crop production. In two field studies comparing no-tillage with standard tillage operations (following wheat silage harvest and before corn seeding), we estimated that 0.89 and 0.97 inches more water was retained in the no-tillage soil than in the tilled soil. In three field studies on residue coverage, we recorded that about 0.56, 0.58 and 0.42 inches more water was retained in residue-covered soil than in bare soil following 6 to 7 days of overhead sprinkler irrigation. Assuming a seasonal crop evapotranspiration demand of 30 inches, coupling no-tillage with practices preserving high residues could reduce summer soil evaporative losses by about 4 inches (13%). However, practical factors, including the need for different equipment and management approaches, will need to be considered before adopting these practices.

Published

2012

4. Water sensors with cellular system eliminate tail water drainage in alfalfa irrigation

Author

Saha, Rajat, Raghuwanshi, Narendra S, Upadhyaya, Shrinivasa K, Wallender, Wesley W., and Slaughter, David C

Subjects

Natural Resources, Cellular communication, alfalfa, water arrival sensor, cutoff irrigation, Biological Engineering, Civil Engineering

Abstract

Alfalfa is the largest consumer of water among all crops in California. It is generally flood-irrigated, so any system that decreases runoff can improve irrigation efficiency and conserve water. To more accurately manage the water flow at the tail (bottom) end of the field in surface-irrigated alfalfa crops, we developed a system that consists of wetting-front sensors, a cellular communication system and a water advance model. This system detects the wetting front, determines its advance rate and generates a cell-phone alert to the irrigator when the water supply needs to be cut off, so that tail water drainage is minimized. To test its feasibility, we conducted field tests during the 2008 and 2009 alfalfa growing seasons. The field experiments successfully validated the methodology, producing zero tail water drainage.

Published

2011

5. Sustainable Eco-Systems under Land Retirement

Author

Wallender, Wesley W.

Abstract

This study uses five years of field data from the Land Retirement Demonstration Project located in western Fresno County of California to develop a comprehensive theoretical and numerical modeling framework to evaluate the specific site conditions required for a sustainable land retirement ecosystem outcome based on natural drainage. Using field data, principles of mass balance in a control volume, the HYDRUS-1D Software Package for simulating one-dimensional movement of water, heat, and multiple solutes in variably-saturated media, and PEST, a modelindependent parameter optimizer, the processes of soil water and solute movement in root zone and the deep vadose zone were investigated. The optimization of unsaturated soil hydraulic parameters and downward flux (natural drainage) from the control volume against observed vadose zone salinity levels and shallow groundwater levels yield difficult to obtain natural drainage rate as a function of water table height within the control volume. The results show that unsaturated soil hydraulic properties and the downward flux from the soil profile are the critical parameters. A ‘natural drainage approach’ to sustainable land management for drainage impaired land is proposed. With this approach it is feasible to design a sustainable land use regimen for drainage impaired lands in general and retired lands in particular.Further analysis of data on the evolution of vadose zone salinity and perched water levels also show that effective unsaturated soil hydraulic property and the "natural drainage rate" change with average soil water salinity. The results show that at the same pressure head, soil water content is less with higher soil water salinity as compared to lower soil water salinity. It is thus concluded that the use of soil water salinity invariant soil water hydraulic parameters in numerical modeling can seriously compromise prediction, especially for a variable soil water salinity environment.

Published

2009

6. Transition to conservation tillage evaluated in San Joaquin Valley cotton and tomato rotations

Author

Mitchell, Jeffrey, Southard, Randal J., Madden, Nicholaus M., Klonsky, Karen M., Baker, Juliet B, DeMoura, Richard L., Horwath, William R, Munk, Daniel S., Wroble, Jonathan F., Hembree, Kurt J, and Wallender, Wesley W.

Subjects

Plant Sciences, conservation tillage, no-till

Abstract

We compared standard tillage (ST) and conservation tillage (CT) for tomato and cotton production systems, with winter cover crops (CC) and without (NO), in Five Points, Calif., from 1999 to 2003. Conservation tillage reduced tractor trips across the field by 50% for tomatoes and 40% for cotton compared to standard tillage. When averaged over the 2001 to 2003 period (when the conservation tillage systems were established), tomato yields in CTNO were 6 to 8 tons per acre higher than the other treatments. In cotton, the STNO cotton yields during this period were the highest of all treatments and were 276 pounds per acre higher than the CTNO system. In-field dust concentrations were also significantly reduced by conservation tillage. Our results suggest that conservation tillage may be a viable alternative for managing tomato and cotton crops in the San Joaquin Valley, but that fine-tuning of the systems is needed.

Published

2008