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Your Position: Home - Compound Fertilizer - Questions You Should Know about Potassium Fertilizer

Questions You Should Know about Potassium Fertilizer

Author: Heather

Mar. 10, 2025

Potassium: Top 5 Things You Need to Know | BW Fusion

We've talked about nitrogen and phosphorus, and now it's time to break down the next essential nutrient: potassium. From root growth and drought tolerance to photosynthesis and protein, there's not much that this nutrient doesn't impact and improve in crops.

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1. Potassium is known as the 'quality nutrient'

While there are 17 essential nutrients when it comes to plant health, K stands out for how it improves nearly all functions of the plant, and, therefore, the overall plant quality. Potassium is the activator in more than 80 essential enzyme reactions. This is critical in managing environmental stress in plants, including drought, disease and pest tolerance. With the volatility of weather factors we've seen increase over the past few years, building stress tolerance to maintain plant quality is a must.

2. Potassium uptake happens earlier than nitrogen and phosphorus

Time of uptake varies by plant and nutrient, but for the most part, the majority of potassium is absorbed by crops at an earlier growth stage than nitrogen and phosphorus. Plants stockpile this nutrient early in the season, and pull from their reserves later in the year. They can also store K in much greater concentrations than what can be found in the surrounding soil.

But, plants' ability to absorb high concentrations of potassium has its drawbacks. If you apply too much potash, or any other form of K fertilizer, plants will soak up more potassium than they need, which creates an imbalance with magnesium and calcium, often causing a deficiency in those nutrients.

3. Potassium plays a key role in regulating water

Potassium is responsible for water's movement and retention throughout much of the plant. This impacts water pressure and standability. When K is low, lodging can happen. The positive charges on potassium ions attract the negative charges on water molecules, meaning where potassium goes, water goes with it. If your plant is low on potassium, it's likely low on water as well. Because potassium helps support water movement, it also aids in the flow of other elements, such as carbohydrates, throughout the plant.

4. Potassium deficiency is hard to spot from the road

Plants pull potassium from the oldest growth to the newest, so deficiencies can't be easily identified by a glance at the field. Crops may look like they are thriving from the top, but show signs of deficiency lower on the plant. A burned appearance starting at the tip of a leaf and going down the outside can signal potassium deficiency. Plants deficient in K look similar to ones deficient in N, but the yellowing is concentrated on the outside of the leaves with potassium deficiency, whereas nitrogen deficiency causes yellowing that starts in the middle and works its way out.

5. Potassium can be leached through leaf damage

Potassium is found in cell sap, meaning torn and damaged leaves bleed K right onto the ground. Hail is a common culprit of damaged leaves. Hail storms early in the season have a greater bounce-back rate due to the potassium reserves crops can pull from. Unbalanced pH levels caused by over- or under-liming can also cause potassium levels to drop as it is leached away by water.

Potassium Fertilizers: Muriate of Potash or Sulfate of Potash?

Alan Blaylock, Ph.D.

Alan Blaylock, Ph.D.

Nutrien

Senior Agronomist

Dr. Alan Blaylock brings extensive North American and international experience in nutrient management to the agronomy team. University studies and service as a university extension soils specialist prepared him for a long career in the fertilizer industry. Having managed both domestic and global research and education programs, Dr. Blaylock has a wealth of experience in applying science-based nutrient management principles and products to solving practical questions. Dr. Blaylock earned Bachelor of Science and Master of Science degrees in agronomy and horticulture from Brigham Young University and a Ph.D. in soil science from Iowa State University. He has been in agriculture his entire life ' from his childhood on an irrigated farm in eastern Oregon to teaching soil science at Iowa State University to his current role as an agronomist at Nutrien. These diverse experiences helped Dr. Blaylock develop the skills to excel in translating complex scientific principles into practical solutions. Although early in his university studies he explored computer science as a profession, deep family roots in agriculture brought him back to the people and values of his heritage. His career satisfaction comes from helping others improve the performance of nutrients and cropping systems. Dr. Alan Blaylock is a recipient of the Great Plains Soil Fertility Conference Leadership Award. The Fluid Fertilizer Foundation also recognized Dr. Alan Blaylock with the Werner Nelson Award for his outstanding contributions in the development of soil fertility practices and plant nutrition management to increase crop yields for the benefit of North American farmers and consumers

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Potassium (K) is an essential nutrient required by plants in large quantities. Potassium does not become part of the many complex organic molecules in the plant. It moves and performs many of its functions as a free ion, such as regulating plant water pressure, activating enzymes, balancing electrical charges, transporting sugars and starches, and more.1  

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Potassium fertilizers are mined from a variety of geologic potassium salt deposits around the world, some of the richest are in the Canadian province of Saskatchewan. The salts are processed to remove impurities and converted to a variety of fertilizers. Two of the most popular potassium fertilizers derived from these salt deposits are potassium chloride and potassium sulfate. The term 'potash' is a general term that is often used to refer to a variety of potassium fertilizer salts or sometimes more specifically to potassium chloride, the most widely used potassium fertilizer. Potassium chloride is referred to as 'muriate (meaning chloride) of potash' or MOP, while potassium sulfate is sometimes called 'sulfate of potash' or SOP.2,3 

The biggest differences between MOP and SOP are from the anion accompanying the potassium. Potassium chloride and potassium sulfate have advantages and disadvantages determined by the chemistry of these salts, their behavior in soils, and the nutrients supplied in addition to potassium.  Both contain essential nutrients required by all crops. Potassium chloride supplies chloride, the ionic form of the element chlorine and an essential micronutrient. Potassium sulfate supplies plant-available sulfate-sulfur. Both MOP and SOP contain a high potassium percentage (60 or 62 percent as K2O for MOP and 50 percent K2O for SOP). The potassium in both fertilizers is in the same potassium form, and both salts are water soluble, though the water-solubility of potassium sulfate is about one-third that of potassium chloride.3 Potassium chloride could be dissolved in water for spray or fertigation applications while potassium sulfate would not be suitable for these applications. 

The biggest disadvantage of potassium sulfate is cost. Potassium chloride is about 40 to 50 percent less expensive per pound of K2O than SOP. The biggest disadvantage of potassium chloride is its high salt index (116 for MOP 0-0-60 vs. 46 for SOP 0-0-50)4 and chloride content. Potassium sulfate is often preferred over potassium chloride for some chloride-sensitive crops such as potatoes, tobacco, some vegetables and fruits, some tree crops like almonds, walnuts and citrus, although these sensitivities are highly dependent on growing conditions, soil salinity, and salinity and chloride in irrigation water.5 Some studies show concerns for chloride may be warranted in some situations, but most studies show little if any difference in field performance of these two potassium sources provided sulfur or chloride is not deficient, and provided the total chloride from soil salinity or irrigation water is within the tolerance of the specific crop.  For example, potato growers often use SOP as the potassium source because of concerns about chloride sensitivity, even though research indicates negative effects of chloride and an advantage of SOP over MOP are not common.6 Anecdotal reports of comparisons and grower experience are varied. 

Chloride affects plants primarily through increasing osmotic potential of soil water. In other words, chloride salts increase the soil salinity which interferes with a plant's ability to take up water. Even in chloride-sensitive crops, studies and observations indicate crops respond to the overall increased osmotic potential before chloride reaches toxic levels. To understand if chloride in the fertilizer is a specific concern, one must evaluate total salt loads, potassium rate, and growing conditions. 

One can compare the osmotic effect of the two sources by calculating the soil-water salt concentration resulting from applications of MOP or SOP at a given potassium rate and multiplying by the osmotic coefficients for the respective salts. When applied to achieve the same potassium concentration in soil, the osmotic potential of MOP is about 1.3 times the osmotic potential for SOP, but the total salt contribution from either material at practical fertilization rates is still very small. The effect of 100 lbs of MOP per acre (60 pounds of K2O per acre) on the osmotic potential of the soil water is calculated as about 0.1 dS/m, a measure of salinity. To put this in perspective, the salinity threshold at which growth of almond ' a sensitive crop ' is not impaired is listed as 1.5 dS/m in the saturated soil extract (electrical conductivity of the extract, or ECe, the standard laboratory measure of soil salinity).7,8 The threshold ECe for strawberry, carrot, onion, and common bean, other sensitive crops, is 1.0 dS/m. The amount of chloride added with normal fertilizer rates would usually be well below the injurious chloride concentrations published for chloride-sensitive crops.9 Sensitive crops begin to show leaf injury at 0.1-0.3 percent chloride in the leaf tissue.9,10 Therefore, unless the total soluble salt and/or chloride load in the soil or irrigation water is near or above the threshold salinity tolerance for the intended crop, potassium source effects are unlikely to have any practical consequence. Note that low precipitation rates and deficit irrigation can exacerbate salt and chloride toxicity issues.9,10 If soil or irrigation water salinity is near or above tolerance thresholds, chloride and salt effects should be managed with potash application rate and timing, possible split applications, maintaining appropriate leaching fractions, and substituting some or all of the MOP with SOP.

Some factors that influence whether potassium chloride use presents a potential risk are:

  • ECe (measure of salt concentration) and chemical composition of the irrigation water;
  • Total growing-season rainfall;
  • Fertilizer application timing in relation to the rainy season and planting or growth of the crop;
  • Rate of potassium to be applied and if it will be split into multiple applications; and
  • Use of deficit irrigation or irrigation amount plus rainfall less than crop need.

While specific examples of MOP vs. SOP comparison studies in sensitive crops are not common in the recent published literature, one recent example for almond production in California is shown below.11  In this study over five years, only one case produced a significant advantage of SOP over MOP ' with fan jet irrigation delivery.   

Emerging biostimulant technologies may also be available to mitigate salt effects or increase salt tolerance. Research with some of these materials is showing promise in mitigating or reducing salinity stress. The grower should study available third-party research and do on-farm tests with these products before large scale use. More research is needed, but some early returns from the research being done indicate these products could facilitate additional management options. 

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