Jun 15, 2022Whiteflies Building Up, Adults on the MoveTo contact John Palumbo go to: jpalumbo@ag.Arizona.edu
Considering everything we do to grow a crop in Arizona, besides perhaps selecting the variety of the crop to be grown, irrigation is clearly the most important agronomic (crop and soil) aspect of crop management. The fact that Arizona consistently produces the highest yields and quality of crops found anywhere is a testimony to the fact that Arizona growers understand this quite well and they are extremely good at managing irrigation.
Part of what has made Arizona farmers so productive is the constant quest to improve on our irrigation methods, particularly in terms of improving irrigation efficiency. We know there are costs agronomically, economically, and environmentally associated with over- or under-irrigation and we constantly strive to alleviate both forms of irrigation water loss and improve irrigation efficiencies.
Irrigation is often considered as an engineering event and that it is true regarding the conveyance of water from a source and getting it to the field. However, the management of irrigation in the field, and particularly the management of both the timing and amount of irrigation, is completely an agronomic decision and action because the objective is to replenish the plant-available water in the soil for the benefit of the crop.
We have access to many methods and technologies to help improve irrigation management and efficiency (Cotton Inc. Sensor-based scheduling; Ratliff et al., 1983). Irrespective of the technologies or methods being used, all successful methods of irrigation management must deal with two basic issues: 1) tracking crop water use and 2) the replenishment of plant-available water in the soil with an irrigation event (Allen et al., 1988; Datta et al., 2017; Hanson et al., 2000).
For efficient management of irrigation water, there are several aspects of the total water in a soil that are important to recognize and the primary water fraction of interest is referred to as the “plant-available soil-water” (PAW). Figure 1 provides a graphic illustration of three important components of soil water: 1) total water in the soil (TW), 2) PAW, and 3) and unavailable soil-water to plants.
A very simple way to describe PAW in a soil can begin by considering the soil with a “sponge” analogy. If we put a sponge under a water faucet and fully saturate it, then let it hang in suspension, we will see free water draining from the sponge for a short period of time. We can consider a soil profile similarly after an irrigation where the soil will saturate and there will be drainage of the water that the soil cannot physically hold, this is referred to as drainage water, the leaching fraction, or the “gravitational water” (GW). The TW water is retained in the soil after the drainage water has moved out of the wetted zone. The TW is held in the soil due to the matrix forces of the soil particles that adhere to that water, like the forces holding water in the saturated sponge analogy. The TW remaining in the soil after the GW has drained away, contains the PAW and the non-available water that the soil holds by matrix forces stronger than what the plant extract (Figures 1 and 2).
There are physical definitions to describe several critical levels of soil-water content and the forces holding water in the soil. For example, field capacity (FC) is the point at which all the GW water has drained out of a soil. Soil physicists have defined FC as a function of potential energy at -33 kPa (kilopascals). Similarly, the permanent wilting point (PWP) has been defined as the point at which all PAW has been extracted from a soil. The PWP is defined somewhat arbitrarily at a potential energy level of -1500 kPa. The more negative the potential energy value, the lower the soil water content and the stronger the water is held in thin layers by the soil particles.
For practical field management of soil water, it is important to focus on the PAW for each soil and crop. It is important to understand that plants are not all created equal in terms of their capacity to extract water from a soil and some plants can extract more water from a given soil than other plants. For example, native desert plants (xerophytic plants) can extract much more water from a soil than most crop plants. Compared to native desert plants, our crop plants are much more sensitive. Therefore, the PAW illustrated in Figures 1, 2, and 3 are general descriptions but they illustrate an important soil-plant relationship. Each plant species has its own capacity to extract water from the soil and we need to know and understand this characteristic of each crop that we are managing in the field as well as the water holding capacity of the soil. For example, lettuce and most leafy-green vegetable crops are more sensitive to water stress than crops like cotton, wheat, melons, alfalfa, sorghum, etc. Thus, leafy green vegetable crops must be maintained at a higher level of PAW to avoid water stress in contrast to some other crop plants such as cotton, wheat, etc. The PWP for these crops will occur much before the soil-water content reaches the point of -1500 kPa.
Crop plants will draw upon the PAW fraction to sustain themselves physiologically and manage against water stress. Crop demands for water change as a function of stage of growth and environmental or weather conditions. Our fundamental irrigation management goal is to monitor the depletion of PAW in the soil and schedule an irrigation at the proper time and rate to replenish the PAW before the crop goes into water stress. That means we also need to identify the critical level of PAW for the crop in the field to determine when an irrigation is needed so we can avoid water stress on the crop.
The fact that different soil types, determined by soil texture, have different total and PAW holding capacities is well illustrated in Figure 1 and Table 1. Thus, it is important to know the soil type prevalent in any field to gauge the amount of PAW that a soil can hold. This will help determine to what extent the soil-water can be depleted and the amount of irrigation water needed to replenish the PAW.
There are many methods and technologies to measure soil-water and PAW to assist in irrigation management. However, the most fundamental method is to sample a soil and estimate “plant-available” water status by “feel”, by literally holding the soil in your hand and estimating the amount of plant-available water that is present.
A good way to calibrate the feel method is to check the soil in a field a few hours after an irrigation event when the GW has drained away and the soil is at FC. The next critical point to identify by the feel method is the soil-water content just before the plants begin to show any sign of water stress. The difference between those two points is the PAW that we are managing in the field. That critical point in the soil-water content that we need to recognize for managing irrigations for crop plants will still have a significant amount of PAW left in the soil but that is because the goal in crop management is to avoid plant water stress, which is signaled by the plant with wilting. Thus, that critical point for irrigating most crop plants is to do so just before the plant begins to experience water stress and show any sign of wilting.
To determine the moisture level in the soil we need to dig down with a shovel, soil probe, or with a soil auger to at least a depth of about 6-12 inches to get a representative soil sample. In general, for many crops and certainly vegetable crops, if the soil forms a tight ball and leaves a wet outline on your hand when you squeeze it, we can delay irrigation until the ball of soil, while still slightly moist and cool to the touch, is dry enough that it begins to crumble at the edges. The depth and time of irrigation should be long enough to fill the entire root zone of the plant, which will be dependent on both the soil texture (Table 1) and the level of soil water depletion.
Tracking and managing PAW water in the soil is a fundamental acquired skill that serves as a check on the irrigation scheduling methods or technologies being used and it remains an extremely valuable skill for anyone managing irrigations. We have many technologies available for irrigation management but a farmer or agronomist’s ability to recognize and understand these relationships and develop the necessary field skills is fundamental to good crop management. Identifying critical points in soil water content and plant growth, such as FC, PAW, and PWP by sampling a soil and making good estimates in the field by watching the crop and noting the various stages in crop development, serve a farmer or agronomist as a good standard and check on any technology being employed for irrigation management.
Farmers and agronomists learn to watch a crop in the field and recognize very subtle changes in leaf color and condition and they can also recognize the crop response and relationship to soil water content. That gives them the capacity to anticipate the optimum timing for the next irrigation. Farmers and agronomists understand these relationships among crop plants, soil water content, and the critical points for irrigation management. Irrigation management is an example of the blending of art and science that goes into good crop management, and it is certainly important in Arizona agriculture.
Table 1. Soil texture and water holding capacity.
Figure 1. Soil volume, soil texture, and water holding capacity relationships.
Figure 2. Soil water content relationship to plant-available water.
Figure 3. Soil moisture classes and important points on the soil moisture relationship curve. (Kansas State University Agronomy Department, Soil Laboratory Manual, soil and water relationships.)
Allen, R. G., Pereira, L. S., Raes, D., & Smith, M. (1998). Crop evapotranspiration-Guidelines for computing crop water requirements-FAO Irrigation and drainage paper 56. FAO, Rome, 300(9), D05109.
Cotton Incorporated. Sensor-Based Scheduling. Retrieved from
Datta, S., S. Taghvaeian, and J. Stivers. 2017. Understanding Soil Water Content and Thresholds for Irrigation Management. Oklahoma Cooperative Extension Service, BAE-1537
Hanson, B., Orloff, S., & Peters, D. (2000). Monitoring soil moisture helps refine irrigation management. California Agriculture, 54(3), 38-42.
Kansas State University Agronomy Department, Soil Laboratory Manual, soil and water relationships. https://kstatelibraries.pressbooks.pub/soilslabmanual/chapter/soil-and-water-relationships/
Ratliff, L., Ritchie, J., & Cassel, D. (1983). Field-measured limits of soil water availability as related to laboratory-measured properties. Soil Science Society of America Journal, 47(4), 770-775.
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 07, Published 4/6/2022Finger weeders are an in-row weeding tool made out of flexible rubber. Pairs are centered on the seed row and overlapped slightly to remove in-row weeds. Our experience has been that they are effective at removing small (3-4 leaf) weeds, but not large or well anchored large weeds. A Texas A&M University colleague shared that they were able to regularly remove 3-4 inch tall Palmer Amaranth in cotton with a cultivator configuration developed by organic cotton grower Carl Pepper. I was pretty impressed. I think you will be too. Check it out by clicking here or on the image below.
we are all aware the most commonly used herbicides in lettuce production are
Kerb (Pronamide), Balan (Benefin), and Prefar (Bensulide). Our weed complex for
lettuce grown in the low desert includes summer annual weeds grasses and
broadleaves early in the season as well as winter annuals, which are a problem
during the cooler months. Most of these are controlled with preemergent
herbicides although escapes are common and must be controlled postemergence.
Occasionally when herbicides and cultural practices are not sufficient
expensive hand weeding is required for commercially acceptable weed control. To
illustrate numbers from our 2016 Crop losses report showed that 91% of the
lettuce surveyed required some hand hoeing even when 82% of the acres was
treated with Pronamide. Also Bensulide and Benefin were applied at lower
Therefore, evaluation of new effective herbicides is always welcomed. We conducted a couple of projects at the Yuma Agricultural Center to look at weed management in transplanted lettuce to determine Pre and Post-Transplant weed control as well as crop safety of other active ingredients such as S-metholachlor (Dual Magnum), Pendimethalin (Prowl), DCPA (Dacthal) and compare them with Pronamide (Kerb) and other products.
Transplanting lettuce and the use of planting tape has opened the possibility of using herbicides that injure direct seeded lettuce but may be safer to plants with a developed root system. Additionally, they could show more efficacy in controlling some weeds present in our area.
We are still collecting results from these trials and will publish them soon in this Newsletter as well as in the upcoming Lettuce Crop Losses Workshop.
Prowl Applied Pre-transplant