May 4, 2022Spider Mites on Spring Melons 2022To contact John Palumbo go to: jpalumbo@ag.Arizona.edu
Throughout the desert Southwest and across the nation, we have continued to experience high prices for fertilizers used in crop production agriculture. Accordingly, there are a lot of concerns and many anecdotes being passed around in an effort to understand the causes. Following a review of the current situation, the conditions that have created these high fertilizer prices, and the prospects for the future; there are many factors involved.
What we are experiencing is illustrated nicely in Figure 1, which describes the pattern of anhydrous ammonia (NH3) costs since September 2008. A very similar story is told in review of the costs for urea (46-0-0), diammonium phosphate (DAP, 18-46-0), and most other fertilizer materials. The high price trends we are now seeing began in September 2020.
Fertilizer prices also experienced a rapid increase in 2008 when nitrogen (N) fertilizer prices increased 32%, phosphate 93%, and potash 100%. Prices then dropped to pre-2007 levels by the end of 2009 and in review the surge was primarily due to high global and national demand and low inventories. The conditions we are now experiencing differ from the 2008 situation.
To better understand this current rise in fertilizer prices it is important to recognize that fertilizer is a global commodity and 44% of all fertilizer materials are exported to a different country. Thus, fertilizer production and prices are affected by other countries demanding fertilizer and the transportation rates to get the fertilizer to the final destination are all important factors.
The U.S. is the third-largest producer of fertilizers globally, and we require the importation of N, phosphorus (P), and potassium (K) to fully meet domestic demand. The U.S. fertilizer dealers and producers pay the price defined by the global market and that include the costs for the base fertilizer, other fertilizer materials, and the transportation requirements.
Anhydrous ammonia (NH3) provides a good example of the U.S. production in relation to the rest of the world. In 2020 NH3 was produced at 36 domestic plants and shipped around the country by pipeline, rail, barge, and truck. As of 2018, U.S. ranked second with 11.6% of global in NH3 production. China at 24.6% led in global NH3 production and India was ranked third with 11.3%.
For phosphate fertilizer production, the U.S. ranked 2nd with 9.9% of global production, led by China at 37.7%, and India with 9.8%.
For the mining and processing of potash (K2O) deposits, Canada is the global leader with 31.9% of global production, followed by Belarus with 16.5%, and Russia with 16.1%. The U.S. produces 0.8% of global potash and ranks 11th in the production of the global supply
Thus, the U.S. is not the sole or dominant player in the global fertilizer industry or market. In point of fact, the U.S. share in terms of global use has dropped from 25% in 1961 to 10% in 2018.
Another major factor to consider are the energy requirements for the production and transport of fertilizer materials. Fertilizer production facilities require a large amount of energy to convert the raw chemical materials into their applicable farm-use state. This is very important in terms of N fertilizers.
There are two basic methods of fixing atmospheric diatomic N gas (N2), which is biologically inert and represents 78% of the earth’s atmosphere. The first, is the natural and miraculous process of biological N fixation which converts inert N2gas from the atmosphere into ammonium-N (NH4). The second is the industrial process, which is also amazing, where anhydrous ammonia is produced by the Haber-Bosch process and atmospheric N2 is combined with hydrogen (H) to synthesize the ammonia (NH3). This reaction is not thermodynamically favorable under natural conditions and huge amounts of energy with high temperatures and pressure are required to accomplish the process. In the Haber-Bosch process, natural gas is the H source and it also the energy source for further N fertilizer synthesis.
Energy costs account for 70% to 90% of the fertilizer production variable costs in the synthesis process. For example, 33 million metric British thermal units (MMBtu) per material ton of NH3 are required to make the conversion in the Haber-Bosch process. Natural gas prices have risen dramatically over the past year, especially in Europe where more than a 300% increase has been experienced since March 2021. This has forced many European Union N plants to close.
The aforementioned factors are dominating the increase in fertilizer prices that we are now experiencing. There are also other important factors including supply chain disruptions, trade duties, and geopolitics. These latter factors tend to get a lot of attention in the agricultural communities and the media often exacerbates that impression. But we see from this basic review, that there are many factors at play, and we can also better understand why fertilizer prices are not likely to come down soon.
Myers, S. and N. Nigh. 2021. Too Many to Count: Factors Driving Fertilizer Prices Higher and Higher. Farm Bureau. https://www.fb.org/market-intel/too-many-to-count-factors-driving-fertilizer-prices-higher-and-higher
Figure 1. Pattern of anhydrous ammonia (NH3) costs since September 2008.
Figure 2. Pattern of U.S. share in the global nutrient market since 1961.
Last year we had a lot of watermelon fields infected with Fusarium from Winterhaven to Yuma, Wellton, and Mohawk Valley. Rain, and overwatering of fields when plants set fruits might have contributed to the disease development.
Fusarium wilt of watermelon, caused by Fusarium oxysporum f. sp. niveum, is one of the oldest described Fusarium wilt diseases and the most economically important disease of watermelon worldwide. It occurs on every continent except Antarctica and new races of the pathogen continue to impact production in many areas around the world. Long-term survival of the pathogen in the soil and the evolution of new races make management of Fusarium wilt difficult.
Symptoms of Fusarium can sometimes be confused with water deficiency, even though there is plenty of water in the field. In Yuma valley we have seen fusarium problem in some overwatered fields.
Initial symptoms often include a dull, gray green appearance of leaves that precedes a loss of turgor pressure and wilting. Wilting is followed by a yellowing of the leaves and finally necrosis. The wilting generally starts with the older leaves and progresses to the younger foliage. Under conditions of high inoculum density or a very susceptible host, the entire plant may wilt and die within a short time. Affected plants that do not die are often stunted and have considerably reduced yields. Under high inoculum pressure, seedlings may damp off as they emerge from the soil.
Initial infection of seedlings usually occurs from chlamydospores (resting structure) that have overwintered in the soil. Chlamydospores germinate and produce infection hyphae that penetrate the root cortex, often where the lateral roots emerge. Infection may be enhanced by wounds or damage to the roots. The fungus colonizes the root cortex and soon invades the xylem tissue, where it produces more mycelia and microconidia. Consequently, the fungus becomes systemic and often can be isolated from tissue well away from the roots. The vascular damage we see in the roots is the defense mechanism of the plant to impede the movement of pathogen.
Disease management include planting clean seeds/transplants, use of resistant cultivars, crop rotation, soil fumigation, soil solarization, grafting, biological control. An integrated approach utilizing two or more methods is required for successful disease management.
Vol. 13, Issue 3, Published 2/9/2022
Over the last couple of years, we have been investigated the use of band-steam to control weeds and soilborne pathogens. The technique has been discussed in previous UA Veg IPM articles (Vol. 12 (5), Vol. 11 (15). Briefly, the concept behind band-steam is to disinfest narrow bands of soil centered on the seedline using high temperature steam prior to planting.
Trials results have been impressive, particularly for in-row weed control (Fig. 1). We’ll be demonstrating our prototype band-steam applicator (Fig. 2) and sharing study results at the 2022 Southwest Ag Summit Field Demo, February 23rd. More information about the event can be found at: https://yumafreshveg.com/southwest-ag-summit/. I look forward to seeing everyone there.
If you are interested in trying band-steam on your farm, please let me know. We are in the process of constructing a second-generation band-steam applicator that has a higher capacity steam generator and simpler design than our first prototype and are seeking collaborators.
This work is partially funded by the Arizona Specialty Crop Block Grant Program.
Fig. 1. Weed control in seedline of beds treated with band-steam (center and left bed) and untreated (right).
Fig. 2. Band-steaming bed seedlines prior to planting in preparation for the 2022 Southwest Ag Summit Field Demo, February 23rd (https://yumafreshveg.com/southwest-ag-summit/).
Pigweeds are some of the most common summer annual broadleaf weeds in the low deserts. Although they are often lumped together, there are 4 different species of pigweed that are common here and more than 10 species that occur as weeds in California and Arizona. Their growth habits and response to herbicides are similar. It is easy to identify them by physical characteristics but one species of pigweed can hybridize with another and become less distinguishable.
Palmer Amaranth (Amaranthus palmeri) is probably the most common pigweed species found in this region. It is very aggressive and fast growing and can become 6 feet tall or higher if uncontrolled. It has one thick stem and several lateral branches. The leaves are lance shaped, hairless and have distinctive white veins on the underside. It has flowering tassels that become stiff and spiny. This species has become resistant to Glyphosate in many parts of the county.
Redroot Pigweed (Amaranthus retroflexus) is probably the second most common pigweed species. It is shorter and the seed heads are smaller, in clusters and have stiff spine-like scales. It has leaf hairs on the margins and the veins are often reddish. The lower stems are often reddish. This species will hybridize with Palmer Amaranth and become less distinguishable.
Tumble Pigweed (Amaranthus albus) is very different from Palmers or Redroot. It grows lower to the ground and has many branches that turn upright. The leaves are much smaller and narrower. The numerous stems are light green rather than red. The seed heads are small, spiny and at the base of the leaves rather than in long terminal spikes. When mature, the branches are sticky, stiff bristles that break off at the ground and tumble with the wind.
Prostrate Pigweed (Amaranthus blitoides) is very similar to Tumble Pigweed but the stems are more prostrate, grow close to the ground and form mats. The stems and leaves are smaller and reddish rather than light green.