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Sulfur application for organic blueberries

Well, I didn’t do myself any favors with my poor tracking of soil pH before planting the blueberries. Between the clay soils and overestimation of the buffering effect of decaying organic matter placed into raised beds, my soils were slightly alkaline at the time of planting in the spring. With fall approaching, it was time to apply sulfur while the soil microbes are still active.

Sulfur is not biologically active as its approval for organic uses may insinuate, but it is literally just an element from the periodic table. It is mined and shipped out in its pure form (if you are lucky enough to find pure sulfur) or in my case, cut with 10% inert fillers.

Now it is time to calculate the application rates which I have discussed before. Below are the tables from that discussion. Ohio State University Extension is the source of the Table 1 while Table 2 is the same but with my calculations converting the application rates from pounds of sulfur per acre to pounds of sulfur per 1000 square feet.

 

Table 1. Rates of elemental sulfur required to decrease soil pH to a depth of 6 inches.
Desired change in pH Application rate based on soil texture1
Sand Silt loam Clay
———————– lb S/A ———————-
8.5 to 6.5 370 730 1460
8.0 to 6.5 340 670 1340
7.5 to 6.5 300 600 1200
7.0 to 6.5 180 360 720
8.5 to 5.5 830 1660 3310
8.0 to 5.5 800 1600 3190
7.5 to 5.5 760 1530 3050
7.0 to 5.5 640 1290 2580
1 Assumptions—cation exchange capacity of the sandy loam, silt loam, and clay soil are 5, 10, and 20 meq/100 g, respectively; soils are not calcareous.

 

Table 2. Rates of elemental sulfur required to decrease soil pH to a depth of 6 inches.
Desired change in pH Application rate based on soil texture1
Sand Silt loam Clay
———————– lb S/1000 sq. ft ———————-
8.5 to 6.5 8.5 16.8 33.5
8.0 to 6.5 7.8 15.4 30.8
7.5 to 6.5 6.9 13.8 27.5
7.0 to 6.5 4.1 8.3 16.5
8.5 to 5.5 19.1 38.1 76.0
8.0 to 5.5 18.4 36.7 73.2
7.5 to 5.5 17.5 35.1 70
7.0 to 5.5 14.7 29.6 59.2
1 Assumptions—cation exchange capacity of the sandy loam, silt loam, and clay soil are 5, 10, and 20 meq/100 g, respectively; soils are not calcareous.

I’ve brought my blueberry beds from 8.6 to just below 7 with other efforts this year. For that 120 square foot bed, the calculations are as follows:

[Application rate for clay soils to lower pH from 7 to 5.5] * [Area of blueberry bed] / [Area of application rate]

[59.2 pounds] * [120 square feet] / [ 1000 square feet] = 7.1 pounds

Then for the remaining unplanted bed around 8.5 pH:

[Application rate for clay soils to lower pH from 8.5 to 5.5] * [Area of blueberry bed] / [Area of application rate]

[76 pounds] * [120 square feet] / [ 1000 square feet] = 9.1 pounds

So, 16.2 pounds total.

The process:

Buy agricultural sulfur. It was $22/50 pounds at my local feed store.

Weight out the amount needed from the above calculations

Apply sulfur

Give the soil microbes a few months to digest the sulfur and lower the pH

The last picture shows the sulfur on top of the mulch, spread lightly around plants and their active roots while applied more heavily in the spaces between plants, which is only done by necessity. In the unplanted blueberry bed the sulfur was applied evenly to bare soil then covered by mulch.

From this point on, test the soil every year or every other year. Repeat the above process as needed!

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My strategy for acidifying soils

In November, my soils tested near a pH of 8 due to the limestone parent and its alkaline calcium contributions. I figured that laying down partially composted horse manure with its pine bedding, mulching it, and letting it compost for another 6 months would help buffer the pH into more manageable levels. Knowing that the blueberry bushes were set to arrive later in the week, I used my quick and imprecise soil kit:

wpid-img_20150512_142142.jpg

Uh oh!

It is apparent that more action is required.

What acidifying soils actually does:

For some reason landscape designers absolutely love putting Pin Oaks in the soil islands in parking lots. No consideration is given to the requirement of these trees to grow in low pH soils. As a result, the trees can’t obtain iron through its roots and wind up chlorotic, or yellowing sick leaves year round. This is the same condition that blueberries will face in too alkaline of soil.

Remember anions and cations from high school chemistry? I’ll spare the most gruesome of details regarding what is going on in soils with varying pH. An alkaline soil is high in cations like calcium or magnesium effectively ties up necessary nutrients in soil like iron due to a low anion exchange capacity.

Further exacerbating the iron uptake issues is that iron is immobile meaning that within a plant, iron cannot be moved from old growth to new growth. The iron requirement in every bit of growth of new leaves, fruit, buds etc. must come from the soils. That is why pH is such a big deal with plants like blueberries!

Acidifying soil strategies:

Attempts to acidify soils can be broken into two categories: Temporary and Slightly Less Temporary. Biologically healthy and active soils have tremendous buffering capabilities in regards to pH. Whatever the motivation to grow a plant like blueberries in alkaline soils like I am doing, the gardener needs to understand that the soil will need constant maintenance to maintain a low pH.

Slightly less temporary acidification means

Slow release soil amendments will release acid as the soil microbes process the parent material of the amendment. The only organically-approved material here is elemental sulfur. While certainly not biologically organic as one would intuitively assume, it still gets organic certification because is is nothing more than a basic element off the periodic table that is found in soils. Application rate depends on the current pH and the structure of the soil. The below table provides a guide with units of pounds per acre. The table below contains the figures once I converted to pounds per 1000 square feet (source):

 

Table 1. Rates of elemental sulfur required to decrease soil pH to a depth of 6 inches.
Desired change in pH Application rate based on soil texture1
Sand Silt loam Clay
———————– lb S/A ———————-
8.5 to 6.5 370 730 1460
8.0 to 6.5 340 670 1340
7.5 to 6.5 300 600 1200
7.0 to 6.5 180 360 720
8.5 to 5.5 830 1660 3310
8.0 to 5.5 800 1600 3190
7.5 to 5.5 760 1530 3050
7.0 to 5.5 640 1290 2580
1 Assumptions—cation exchange capacity of the sandy loam, silt loam, and clay soil are 5, 10, and 20 meq/100 g, respectively; soils are not calcareous.

 

Table 1. Rates of elemental sulfur required to decrease soil pH to a depth of 6 inches.
Desired change in pH Application rate based on soil texture1
Sand Silt loam Clay
———————– lb S/1000 sq. ft ———————-
8.5 to 6.5 8.5 16.8 33.5
8.0 to 6.5 7.8 15.4 30.8
7.5 to 6.5 6.9 13.8 27.5
7.0 to 6.5 4.1 8.3 16.5
8.5 to 5.5 19.1 38.1 76.0
8.0 to 5.5 18.4 36.7 73.2
7.5 to 5.5 17.5 35.1 70
7.0 to 5.5 14.7 29.6 59.2
1 Assumptions—cation exchange capacity of the sandy loam, silt loam, and clay soil are 5, 10, and 20 meq/100 g, respectively; soils are not calcareous.

 

 

As sulfur takes months to have an effect of soil pH, I regret not applying it in November with the installation of the compost. I did rent a tiller and worked 8 pounds into my 80 square foot blueberry bed. I will continue to topdress with elemental sulfur (under the mulch layer). Now I’ll have to work slowly and carefully with the living plants using temporary means while the sulfur goes to work.

Peat moss is another amendment that has been proven to significantly boost blueberry yields. Personally, I don’t think peat moss deserves a place in horticulture as it is a not renewable resource and is extracted from fragile ecosystems. Here is a good article on the subject.

Temporary acidification means

Acidifying fertilizers are one method to maintain soil pH. As there is a large livestock feedmill nearby, I use 50+ pounds sacks of cottonseed meal ($12) as a fertilizer that both provides nitrogen and acidifies soil as it breaks down. It is pelletized which I initially did not like, but after the first rain since applying 200 pounds of it, the pellets explode in volume and hold quite a bit of moisture.

Acidic irrigation is another part of my strategy. I use 2 tablespoons of the cheap distilled white vinegar per gallon of water to irrigate the root zones. I use a much more aggressive rate to apply between plants where no roots yet exist. I repeat this weekly as vinegar only temporarily ties up calcium! Oak tea is an experiment I am currently trying to find a more biological approach than distilled vinegar.

Acidic mulching: mulching materials like pine straw/needles have long been recommended to help acidify soils. While acidifying soils has tossed some obstacles to my biological approach to raising food crops, I still want to mulch in a manner that promotes mycorrhizal fungal dominance that all woody species need. Therefore I mulch with shredded wood from tree tops but apply elemental sulfur below the mulch.

 

Conclusion

The best time to acidify soil is at least 2-3 months before planting. I missed the boat here and now have that added complications of working with living roots that will be burned by a direct application of strong acid. I hope to be able to gradually lower the pH of the soils before the bushes begin producing berries.

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