Borgmann Aquaponics Hydroponics
This concise overview serves as a guide to estimate the order of magnitude required for analytical techniques when analyzing and controlling the nutrients used for plant fertilization.
The analytical quality in chemistry has already reached a precision that is unnecessary for our purposes of controlled fertilization. To avoid using a sledgehammer to crack a nut when selecting different analysis methods and equipment, we have compiled a highly condensed overview of the necessary accuracies sufficient for monitoring individual additives. The chosen analytical technology has a significant impact on overall operating costs.
In addition to monitoring essential nutrients, control measures are also necessary to prevent over-fertilization. Nutrients from fish farming must not exceed certain concentrations, as this would otherwise impair optimal plant growth.
There is now a very large number of analytical methods on the market, which differ greatly both in the technology used and in on-site application. This overview helps you, even without our consulting services, to obtain quotes from various manufacturers that precisely meet your needs. Here is a random selection of manufacturers.
Here you will find the essential compounds required for plant growth. Depending on the plant and/or growth stage, the form of application, the chemical compound in which the desired "substance" is bound, may vary. In traditional cultivation (in soil), microorganisms and fungi facilitated the breakdown of necessary compounds. Since hydroponics lacks microorganisms to perform this task, this remains an ongoing area of fundamental research.
Compounds and Trace Elements / Orders of Magnitude in Nutrient Solutions
Conversion: mmol/L | mg/L | ppm
| Element / Compound | Name | mmol/L | mg/L | ppm |
|---|---|---|---|---|
| Macronutrients | ||||
| K | Potassium | 3 – 8 | 117 – 313 | 117 – 313 |
| Ca | Calcium | 1 – 4 | 40 – 160 | 40 – 160 |
| Mg | Magnesium | 0.5 – 1.5 | 12 – 36 | 12 – 36 |
| P | Phosphorus | 0.3 – 1.5 | 9.3 – 46.5 | 9.3 – 46.5 |
| S | Sulfur | 0.5 – 2 | 16 – 64 | 16 – 64 |
| Trace Elements | ||||
| Fe | Iron | 0.010 – 0.040 | 0.56 – 2.24 | 0.56 – 2.24 |
| Cu | Copper | 0.0005 – 0.002 | 0.03 – 0.13 | 0.03 – 0.13 |
| Zn | Zinc | 0.001 – 0.008 | 0.07 – 0.52 | 0.07 – 0.52 |
| Mn | Manganese | 0.001 – 0.008 | 0.06 – 0.44 | 0.06 – 0.44 |
| B | Boron | 0.010 – 0.045 | 0.11 – 0.49 | 0.11 – 0.49 |
| Mo | Molybdenum | 0.0001 – 0.001 | 0.01 – 0.10 | 0.01 – 0.10 |
| Nitrogen Compounds | ||||
| NO₃ | Nitrate | 0.8 – 3.2 | 50 – 200 | 50 – 200 |
| NO₂ | Nitrite | 0 – 0.22 | 0 – 10 | 0 – 10 |
| NH₄ | Ammonium | 0.06 – 1.11 | 1 – 20 | 1 – 20 |
| Fertilizer Salts and Chelates | ||||
| KNO₃ | Potassium Nitrate | 0 – 8 | 0 – 809 | 0 – 809 |
| Ca(NO₃)₂ | Calcium Nitrate | 0 – 8 | 0 – 1312 | 0 – 1312 |
| MgSO₄ | Magnesium Sulfate | 0.5 – 2 | 60 – 241 | 60 – 241 |
| Fe-EDTA | Iron Chelate | 0.010 – 0.040 | 3.5 – 14 | 3.5 – 14 |
| H₃BO₃ | Boric Acid | 0.010 – 0.045 | 0.62 – 2.78 | 0.62 – 2.78 |
| MnSO₄ | Manganese(II) Sulfate | 0.001 – 0.008 | 0.17 – 1.35 | 0.17 – 1.35 |
| ZnSO₄ | Zinc Sulfate | 0.001 – 0.008 | 0.16 – 1.29 | 0.16 – 1.29 |
| CuSO₄ | Copper Sulfate | 0.0005 – 0.002 | 0.08 – 0.32 | 0.08 – 0.32 |
| KCl | Potassium Chloride | not common in nutrient solutions (chloride limited) | ||
| FeSO₄ | Iron(II) Sulfate | chelated form (Fe-EDTA/Fe-DTPA) preferred | ||
| NH₄H₂PO₄ | Ammonium Dihydrogen Phosphate | 0 – 2 | 0 – 230 | 0 – 230 |
| (NH₄)₂HPO₄ | Diammonium Hydrogen Phosphate | 0 – 2 | 0 – 264 | 0 – 264 |
| MoO₃ | Molybdenum Oxide | 0.0001 – 0.001 | 0.014 – 0.144 | 0.014 – 0.144 |
Conversion: Moles, mg/L, and ppm
Conversion: Moles and PPM
A Technical Definition of ppm
What is ppm? And how can something called "parts per million" be represented by mg/L? Parts per million indicates the number of "parts" of one substance in one million "parts" of another. The "part" can be any unit, but when mixing solutions, ppm typically represents units of weight. In this context, ppm indicates how many grams of a solute are present in one million grams of solvent (e.g., water).
1 g solute / 1,000,000 g solvent
When dealing with water at room temperature, it is common to assume that the density of water is 1 g/mL. Therefore, we can rewrite the relationship as follows:
1 g solute in 1,000,000 mL water
Then divide mL by 1000 mL:
1 g solute in 1,000 L water
Dividing both units by 1000 gives:
1 mg solute in 1 L water
Therefore, 1 mg in 1 L water is equivalent to 1 mg in 1,000,000 mg water, or 1 part per million (assuming room temperature and atmospheric pressure of 1 atmosphere).
How to Convert ppm to Moles
To convert ppm to molarity or vice versa, you only need the molar mass of the element or molecule in question. Here is a periodic table for molar masses (top left: atomic weight).
Take the molarity in mol/L and multiply by the molar mass in g/mol to obtain g/L. Then multiply by 1000 to convert grams to milligrams, and you have mg/L for aqueous solutions.
Example: Preparing a NaOH Solution
You have a stock solution of 1 molar NaOH. How do you prepare 1 L of a 200 ppm NaOH solution? NaOH has a molar mass of 39.997 g/mol.
1. Convert 200 ppm to molarity.
First, assume 200 ppm = 200 mg/L. Divide the result by 1000 to get g/L: 200 mg/L ÷ 1000 mg/g = 0.2 g/L.
Next, divide 0.2 g/L by the molar mass of NaOH (Na = 22.99, O = 16, H = 1) to obtain molarity: 0.2 g/L ÷ 39.997 g/mol = 0.005 mol/L.
2. Calculate the dilution recipe.
From step 1, we know the target molarity is 0.005 mol/L. To calculate the dilution, we use the dilution equation: m₁⋅v₁ = m₂⋅v₂
where:
• m₁ — concentration of the stock solution;
• m₂ — concentration of the diluted solution;
• v₁ — volume of the stock solution;
• v₂ — volume of the diluted solution.
We can input the numbers for all variables except the stock solution volume:
1 M ⋅ v₁ = 0.005 M ⋅ 1 L
Rearranging the equation gives the required stock solution volume:
v₁ = 0.005 M / 1 M ⋅ 1 L = 0.005 L
Therefore, we need to dilute 0.005 L (or 5 mL) of stock solution to a final volume of 1 L to obtain a 200 ppm NaOH solution.
How to Calculate ppm from Volume Concentration
To obtain volume-ppm:
Take the molar concentration of the solution in mol/L.
Multiply it by the molar mass in g/mol.
Divide it by the density of the solute in g/cm³.
Multiply everything by 1000 mg/g.
The resulting ppm volume unit is typically μL/L.
Here are more detailed examples for both conversion directions:
How-Tos and Measuring Instruments
Further Information:
https://en.wikipedia.org/wiki/Water_analysis (Local Copy)
SI Prefixes
| Name | Yotta | Zetta | Exa | Peta | Tera | Giga | Mega | Kilo | Hecto | Deca |
|---|---|---|---|---|---|---|---|---|---|---|
| Symbol | Y | Z | E | P | T | G | M | k | h | da |
| Factor | 1024 | 1021 | 1018 | 1015 | 1012 | 109 | 106 | 103 | 102 | 101 |
| Name | Yocto | Zepto | Atto | Femto | Pico | Nano | Micro | Milli | Centi | Deci |
| Symbol | y | z | a | f | p | n | µ | m | c | d |
| Factor | 10−24 | 10−21 | 10−18 | 10−15 | 10−12 | 10−9 | 10−6 | 10−3 | 10−2 | 10−1 |
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