For decades, current agriculture practices have focused on the N-P-K approach to fertility. Many dollars are spent on soil tests, at different depths and testing techniques. Recommendations for nitrogen, phosphorous and potassium are made based on the results.
Biological Ionization takes a different approach to the fertility needs of the soil and the crop being grown. Minerals are categorized based on the rotation of the ion and the effect it has on the growing plant. The energy released from the interaction of the anions and the cations, the anions with other anions as well as the cations with other cations is what allows the plant to grow. Providing the best combinations of cations and anions to match the development of the growing plant is the goal of this approach.
Anionic minerals promote the growth of the plant vegetatively. Stems, leaves and roots will grow and develop when the plant is growing in this stage. Minerals that are considered anionic are Calcium, Potassium and Chloride. These minerals have a counterclockwise spin and measure from 0-499 units on the Millhouse scale of energy.
Cationic minerals are responsible for the reproductive growth of a plant. This group includes all the minerals not mentioned above. (With the exception of Oxygen, Hydrogen, Nitrogen and Helium, they are described below.) Millhouse unit measurements range from 500-999 and they are considered to have a clockwise spin.
Oxygen, Hydrogen, Nitrogen and Helium are considered to be categorized slightly different. These minerals can be either cationic or anionic depending on the environment that they are found. They are believed to follow the path of least resistance and convert to anionic or cationic as required.
Energy levels (ERGS and Millhouse Units) are very important when the growth of a plant is being considered. Please read the Physics link on the home page for more information.
The plant's main job is to photosynthesize, creating sugar. A plant with increased sugar levels will result in increased energy but also increased nutrition and nutrient density for the consumer. Nutrient density should be the chief goal in the production of food.
All minerals found on the periodic chart have unique characteristics or personalities. These characteristics are found in all environments and don't change from the soil to the plant to the animal. For example, if an electrolyte mineral causes water retention in the human body, it will also retain water in the plants and the soil as well.
Minerals needed for plant growth and production:
Calcium is seen as the backbone, the mediator, the mentor, the organizer. All minerals in the soil should balance to the quantity of water soluble or "available" calcium in the soil. Generally, calcium is believed to play the following roles:
Phosphorous is the workhorse in the soil. All minerals other than Nitrogen should enter the plant in the phosphate form. In cooperation with Calcium, photosynthesis is increased and the production of sugar is greater.
Phosphorus is found in several forms in the soil, i.e.: P1, P2, and P204. P204 is the organic state that is stable in the soil and available to the plants. All other forms of phosphorous require metabolic changes before the plant is able to utilize it.
Characteristics of Phosphate include:
The following three minerals are needed in plant grow, but likely not in the amounts often recommended. All three are considered electrolyte minerals that, along with other functions in the plant, will draw and hold water.
Potassium is an anionic mineral like Calcium, but use of large amounts of potassium for anionic energy will result in a large vegetative plant, but will likely not produce exceptional levels of sugar due to the increased water held by the excess potassium. Excess magnesium levels in the soil will cause complications with structure and hydration. Excess amounts of sulfur will tie up available calcium.
Oxygen is the needed mineral in the soil for the aeration and survival of the aerobic micro-organisms.
For more information about the chemicals needed in plant growth, go to www.aglabs.com.