Jun 15, 2022Whiteflies Building Up, Adults on the MoveTo contact John Palumbo go to: jpalumbo@ag.Arizona.edu
Arizona agriculture utilizes ~ 70% of the water in this state and generates a strong and productive industry. Arizona agriculture generates more than $23B in sales as well as directly and indirectly supporting more than 138,000 Arizona jobs and employing more than 162,000 unique workers. Arizona ranks among leading states in the production of lettuce, spinach, broccoli, cauliflower, cantaloupe, honeydew melons, durum wheat, and other commodities. Arizona is an important area for the seed production of many crops that are used across the U.S. and worldwide. Many Arizona counties rank in the top 1% of all U.S. counties in terms of crop and livestock production (Murphree, 2018).
In response to the Colorado River (CR) water shortage and the current reductions in CR allocations to Arizona via the Central Arizona Project (CAP), which is primarily impacting agricultural irrigation districts in central Arizona, there is an increasing level of scrutiny on agricultural uses of Arizona water. This of course is accentuated with the recognition that agriculture utilizes ~ 70% of the Arizona water supply.
In the irrigation districts along the mainstem of the CR, there is a common adage of “First in use, first in right.” This is a fundamental aspect of the “law of the river”, which is an amalgam of the various laws, agreements, and rulings on the governance of CR water. Therefore, it is important for us to consider and prepare the positive case that can be made for the good stewardship of water resources provided by Arizona agriculture.
One common area of criticism that is directed towards Arizona crop production systems, is the use of surface and flood irrigation systems. The alternative irrigation methods that are commonly advocated for use instead of flood irrigation are methods such as drip irrigation, micro-irrigation systems, sprinklers, etc. Each of these are good irrigation methods and advantageous under the appropriate conditions. However, a good case can be made for the very efficient use of flood irrigation systems, particularly with high-flow turnouts and dead level (or very nearly so) basins for irrigation. When properly managed, these types of flood irrigation systems can be very efficient.
When we know the area to be irrigated, the flow rate of water in the irrigation delivery ditch, and the amount of water needed; then we can determine the proper time or duration for an irrigation event. If we can get fast and uniform coverage of the field to be irrigated, apply the proper volume of water to replenish the plant-available water supply to the soil, then cut off the flow of irrigation water into the field; we can do a very good job of delivery for high water-use efficiency.
To facilitate the process of managing individual irrigations for optimum efficiency, the Irrigator’s Equation can be used to estimate the depth of water applied or time (duration) of an irrigation event.
Q x t = d x A
Where: Q = the flow rate, in cubic feet per second (cfs);
t = the set time or total time of irrigation (hours);
d = the depth of water applied (inches) and
A = the area irrigated (acres).
With an understanding of the dominant soil type in the field being irrigated and the level of soil-water depletion at the time of irrigation, we can estimate the amount or depth of water needed to replenish the soil profile of plant-available water to support the crop and prevent water stress.
In managing crop fields and irrigations, we recognize that soil textures vary in terms of water holding capacities and it is important to understand the dominant soil textures in the field, not only on the surface but also through the depths of the soil profile through the effective rooting depth of the crop, Tables 1 & 2.
Collectively, we can manage surface or flood irrigation systems efficiently. In the crop production arena, it is important to communicate these points effectively.
Table 1. Soil texture and water holding capacity.
2. Depths to which the roots of mature crops will deplete the available water supply when grown in a deep permeable, well-drained soil under average conditions.
Source: Chapter 11, "Sprinkler Irrigation," Section 15, Natural Resources Conservation Service National Engineering Handbook
Murphree, J. 2018. Arizona Agriculture is 23 Billion Dollars Beautiful, Arizona Farm Bureau.
Bindu Poudel, Martin Porchas, and Rebecca Ramirez
Yuma Agricultural Center, University of Arizona, Yuma, AZ
This study was conducted at the Yuma Valley Agricultural Center. The soil was a silty clay loam (7-56-37 sand-silt-clay, pH 7.2, O.M. 0.7%). Lettuce ‘Magosa’ was seeded, then sprinkler-irrigated to germinate seed on Nov 19, 2019 on double rows 12 in. apart on beds with 42 in. between bed centers. All other water was supplied by furrow irrigation or rainfall. Treatments were replicated four times in a randomized complete block design. Each replicate plot consisted of 25 ft of bed, which contained two 25 ft rows of lettuce. Plants were thinned Jan 6, 2020 at the 3-4 leaf stage to a 12-inch spacing. Treatment beds were separated by single nontreated beds. Treatments were applied with a tractor-mounted boom sprayer that delivered 50 gal/acre at 100 psi to flat-fan nozzles spaced 12 in. apart.
Sclerotia of Sclerotinia minor were produced in 0.25 pt glass flasks containing 15 to 20 sterilized 0.5 in. cubes of potato by seeding the potato tissue with mycelia of the fungus. After incubation for 4 to 6 wk at 68°F, mature sclerotia were separated from residual potato tissue by washing the contents of each flask in running tap water within a soil sieve. Sclerotia were air-dried at room temperature, then stored at 40°F until needed. Inoculum of Sclerotinia sclerotiorum was produced in 2 qt glass containers by seeding moist sterilized barley seeds with mycelia of the pathogen. After 2 mo incubation at 68°F, abundant sclerotia were formed. The contents of each container were then removed, spread onto a clean surface and air-dried. The resultant mixture of sclerotia and infested barley seed was used as inoculum. Lettuce ‘Magosa’ was seeded Nov 19, 2019 then sprinkler-irrigation was initiated to germinate seed in double rows 12 inches apart on beds with 42 inches between bed centers. Plants were thinned Jan 6, 2020 at the 3-4 leaf stage to a 12-inch spacing. For plots infested with Sclerotinia minor, 0.13 oz (3.6 grams) of sclerotia were distributed evenly on the surface of each 25-ft-long plot between the rows of lettuce and incorporated into the top 1 inch of soil. For plots infested with Sclerotinia sclerotiorum, 0.5 pint of a dried mixture of sclerotia and infested barley grain was broadcast evenly over the surface of each 25-ft-long lettuce plot, again between the rows of lettuce on each bed, and incorporated into the top 1-inch of soil. Treatment beds were separated by single nontreated beds. Treatments were replicated five times in a randomized complete block design. Each replicate plot consisted of a 25 ft length of bed, which contained two 25 ft rows of lettuce. Control plots received sclerotia but were not treated with any fungicide.
For treatments first applied at seeding, sclerotia were introduced into plots before the first application of treatments. The first application for at seeding treatments was made Nov 20, with an additional application on Jan 9. For treatments first applied after thinning, sclerotia were introduced into plots after thinning before the first application of these treatments, with additional applications as noted in the data sheets. An initial sprinkler irrigation supplied water for seed germination, with subsequent furrow irrigations for crop growth. The final severity of disease was determined at plant maturity by recording the number of dead and dying plants in each plot due to Sclerotinia minor (Mar 18) or Sclerotinia sclerotiorum (Mar 17). As a point of reference, the original stand of lettuce was thinned to about 65 plants per plot.
In nontreated plots, 30 and 37% of lettuce plants were dead or dying due to infection with Sclerotinia minor and S. sclerotiorum, respectively, at the end of the trial. Please refer to the data tables to compare treatments of interest, using the Least Significant Difference Value listed at the bottom of each table to determine statistically significant differences among treatments. Endura+Stragus alternated with Merivon+Stargus, PhD, and Luna Sensation were effective against Sclerotinia sclerotiorum. Endura on seeding water alternated with Merivon at thinning, Luna Sensation at thinning, Endura at thinning alternate with Merivon, Endura_stargus at thinning alternate with Merivon+stargus gave the best results against Sclerotinia minor(see table).
Vol. 13, Issue 4, Published 2/23/2022
Keeping up to date with the latest developments in automated weeding machines is challenging. It’s a very fast-moving space with significant private and public investment. At the 2022 Southwest Ag Summit “Innovations in Weed Control Technologies” breakout session, university experts and cutting-edge innovators will provide updates on the latest domestic and international developments in automated weeding, autonomous ag robots, and non-chemical weed control (agenda below). The session will be held TOMMOROW Thursday, February 24th from 1:30-3:30 pm.
As I mentioned in the last newsletter, we’ll also be demoing our band-steam applicator for controlling soilborne diseases and weeds at the Southwest Ag Summit Field Day. We’ll also have our 2nd generation prototype band-steam applicator on display (Fig. 2). It is simpler in design and has a higher capacity steam generator as compared to our first prototype. This will increase travel speed and thereby work rate. The event is scheduled for TODAY, Wednesday, February 23rd from 10:30 am – 4:30 pm.
For more information about the Southwest Ag Summit, visit https://yumafreshveg.com/southwest-ag-summit/.
Hope to see you there!
This work is partially funded by the Arizona Iceberg Lettuce Research Council, Arizona Specialty Crop Block Grant Program and USDA-NIFA Crop Protection and Pest Management Program.
Fig. 1. “Innovations in Weed Control Technologies” breakout session agenda at the 2022 Southwest Ag Summit. Session will be held Thursday, February 24th at Arizona Western College, Yuma, AZ.
Fig. 2. Prototype band-steam applicator for controlling soilborne pathogens and weeds on display at the 2022 Southwest Ag Summit, Yuma, AZ. Applicator sled and trailer fabricated by Keithly-Williams Fabrication, Yuma, AZ. Steam generator provided courtesy of Simox, Contamine-sur-Arve, France.
Palafoxia arida is a plant from the family Asteraceae also called the Sunflower family. It is native to the Desert regions of California and the SW United States in AZ, NV, CA, UT, Baja California and Sonora. It is an annual weed that grows erect and has rough hairs on the leaves, which are grayish green and narrow or linear. This plant can grow up to 6 ft has a main tap root. The flower heads are about 2-3 cm long with several (up to 40) tubular five lobed florets white to light pink color. Its habitat includes sandy plains, mesas, washes, dunes.
We found this weed abundantly in our Yuma County Survey. The highest populations were found at the Yuma Mesa around fields. Also found in newly established alfalfa fields. Despite the fact that it prefers sandy soils we also detected Palafoxia all across the Yuma County from the Texas Hill area Wellton, Dome Valley to the San Luis Arizona border. Please see Yuma County map below.
The Arizona Vegetable IPM Team will be checking to see if this weed is a possible host for INSV (Inpatiens Necrotic Spot Virus).