Application of Metham Sodium by Sprinkler Irrigation to Control Lettuce Drop Caused bySclerotinia minor

To understand the geographical distribution of lettuce drop incidence and the structure of Sclerotinia minor and S. sclerotiorum populations, commercial lettuce fields were surveyed in the Salinas, San Joaquin, and Santa Maria Valleys in California. Lettuce drop incidence, pathogen species, and mycelial compatibility groups (MCGs) were determined and analyzed using geostatistic and geographical information system tools. Lettuce drop incidence was lowest in the San Joaquin Valley, and not significantly different between the other two valleys. Semivariogram analysis revealed that lettuce drop incidence was not spatially correlated between different fields in the Salinas Valley, suggesting negligible field-to-field spread or influence of inoculum in one field on other fields. Lettuce drop incidence was significantly lower in fields with a surface drip system than in fields with furrow or sprinkler irrigation systems, suggesting that the surface drip system can be a potential management measure for reducing lettuce drop. In the San Joaquin Valley, S. sclerotiorum was the prevalent species, causing drop in 63.5% of the fields, whereas S. minor also was identified in 25.4% of the fields. In contrast, in the Salinas Valley, S. minor was the dominant species (76.1%) whereas S sclerotiorum only observed in only 13.6% fields, in which only a few plants were infected by S. sclerotiorum. In the Santa Maria Valley, both species frequently were identified, with S. minor being slightly more common. Although many MCGs were identified in S. minor, most of them consisted of only one or two isolates. In all, ≈91.4% of the isolates belonged to four MCGs. Among them, MCG-1 was the most prevalent group in all three valleys, accounting for 49.8% of total isolates. It was distributed all over the surveyed areas, whereas other MCGs were distributed more or less locally. Populations of S. sclerotiorum exhibited greater diversity, with 89 isolates collected from the Salinas and San Joaquin Valleys belonging to 37 different MCGs. Among them, the most recurrent MCG-A contained 16 isolates, and 30 MCGs contained only 1 isolate each. Many MCGs occurred within only one or a part of the two valleys. Potential reasons for this abundant diversity are discussed.

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OBTAINING HIGH HARVESTS AND GREEN MASS OF ECHINOCHLOA FRUMENTACEA UNDER CONDITIONS OF SPRINKLER IRRIGATION

Prirodoobustrojstvo ◽

10.26897/1997-6011-2017-2-75-80 ◽

2017 ◽

pp. 75-80

Author(s):

V.I. Zhelyazko ◽

◽

V.M. Lukashevich ◽

Keyword(s):

Sprinkler Irrigation ◽

Green Mass ◽

Echinochloa Frumentacea

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Effects of Furrow Diking on Corn Response to Limited and Full Sprinkler Irrigation

Soil Science Society of America Journal ◽

10.2136/sssaj2002.0222 ◽

2002 ◽

Vol 66 (1) ◽

pp. 222 ◽

Cited By ~ 3

Author(s):

T. A. Howell ◽

A. D. Schneider ◽

D. A. Dusek

Keyword(s):

Sprinkler Irrigation

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Reuse of Wastewaters in Agriculture by Means of Sprinkler Irrigation on a Farmland Area of 3000 ha – Large Scale Experience in Germany

Water Science & Technology ◽

10.2166/wst.1986.0088 ◽

1986 ◽

Vol 18 (9) ◽

pp. 163-173

Author(s):

R. Boll ◽

R. Kayser

Keyword(s):

Large Scale ◽

Treatment Process ◽

Treatment Plant ◽

Sprinkler Irrigation ◽

Paper Briefly ◽

Treatment Results ◽

Sewage Farm ◽

Western Germany ◽

Pre Treatment ◽

Main Components

The Braunschweig wastewater land treatment system as the largest in Western Germany serves a population of about 270.000 and has an annual flow of around 22 Mio m3. The whole treatment process consists of three main components : a pre-treatment plant as an activated sludge process, a sprinkler irrigation area of 3.000 ha of farmland and an old sewage farm of 200 ha with surface flooding. This paper briefly summarizes the experiences with management and operation of the system, the treatment results with reference to environmental impact, development of agriculture and some financial aspects.

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Relationship between Relative Maturity and Grain Yield of Maize (Zea mays L.) Hybrids in Northwest New Mexico for the 2003–2019 Period

Agriculture ◽

10.3390/agriculture10070290 ◽

2020 ◽

Vol 10 (7) ◽

pp. 290

Author(s):

Koffi Djaman ◽

Curtis Owen ◽

Margaret M. West ◽

Samuel Allen ◽

Komlan Koudahe ◽

...

Keyword(s):

New Mexico ◽

Grain Yield ◽

Sprinkler Irrigation ◽

Growing Season ◽

Climatic Conditions ◽

Agricultural Science ◽

Production Optimization ◽

Science Center ◽

Early Season ◽

Climate Conditions

The highly variable weather under changing climate conditions affects the establishment and the cutoff of crop growing season and exposes crops to failure if producers choose non-adapted relative maturity that matches the characteristics of the crop growing season. This study aimed to determine the relationship between maize hybrid relative maturity and the grain yield and determine the relative maturity range that will sustain maize production in northwest New Mexico (NM). Different relative maturity maize hybrids were grown at the Agricultural Science Center at Farmington ((Latitude 36.69° North, Longitude 108.31° West, elevation 1720 m) from 2003 to 2019 under sprinkler irrigation. A total of 343 hybrids were grouped as early and full season hybrids according to their relative maturity that ranged from 93 to 119 and 64 hybrids with unknown relative maturity. The crops were grown under optimal management condition with no stress of any kind. The results showed non-significant increase in grain yield in early season hybrids and non-significant decrease in grain yield with relative maturity in full season hybrids. The relative maturity range of 100–110 obtained reasonable high grain yields and could be considered under the northwestern New Mexico climatic conditions. However, more research should target the evaluation of different planting date coupled with plant population density to determine the planting window for the early season and full season hybrids for the production optimization and sustainability.

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Temporal and Local Heterogeneities of Water Table Depth under Different Agricultural Water Management Conditions

Water ◽

10.3390/w13162148 ◽

2021 ◽

Vol 13 (16) ◽

pp. 2148

Author(s):

Jonathan A. Lafond ◽

Silvio J. Gumiere ◽

Virginie Vanlandeghem ◽

Jacques Gallichand ◽

Alain N. Rousseau ◽

...

Keyword(s):

Water Management ◽

Water Table ◽

Cropping Systems ◽

Irrigation Management ◽

Sprinkler Irrigation ◽

Water Table Depth ◽

Management Systems ◽

Integrated Water Management ◽

Growing Seasons ◽

Good Drainage

Integrated water management has become a priority for cropping systems where subirrigation is possible. Compared to conventional sprinkler irrigation, the controlling water table can lead to a substantial increase in yield and water use efficiency with less pumping energy requirements. Knowing the spatiotemporal distribution of water table depth (WTD) and soil properties should help perform intelligent, integrated water management. Observation wells were installed in cranberry fields with different water management systems: Bottom, with good drainage and controlled WTD management; Surface, with good drainage and sprinkler irrigation management; Natural, without drainage, or with imperfectly drained and conventional sprinkler irrigation. During the 2017–2020 growing seasons, WTD was monitored on an hourly basis, while precipitation was measured at each site. Multi-frequential periodogram analysis revealed a dominant periodic component of 40 days each year in WTD fluctuations for the Bottom and Surface systems; for the Natural system, periodicity was heterogeneous and ranged from 2 to 6 weeks. Temporal cross correlations with precipitation show that for almost all the sites, there is a 3 to 9 h lag before WTD rises; one exception is a subirrigation site. These results indicate that automatic water table management based on continuously updated knowledge could contribute to integrated water management systems, by using precipitation-based models to predict WTD.

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