Plant Growth

What makes Exciter Super AG Adjuvant so different?

How does a small particle size work differently than a larger particle size? All molecules have a positive or negative electrical charge to them, as all living cells are electro-magnetic. These electrical charges and magnetism have an impact on how these molecules/particles behave. When molecules are at the size of  positive molecules attract other positive molecules, contrary to the conventional rules of physics, for as we are all aware, the positive poles of a magnet repel one another and positive and negative poles attract each other in our everyday lives.

Plants, humans and animals, in essence, are electro-magnetic and are governed by the Periodic Law and Table. In photosynthesis, plants require the radiation from the Sun plus 6 molecules of water and 6 molecules of carbon dioxide to make 1 basic sugar molecule and 6 molecules of oxygen. We know that plants emit oxygen into the atmosphere during the photosynthesis process and use that 1 molecule of basic sugar manufactured as the foundational building block for everything that we see growing above ground, producing roots, tree trunks, stems, leaves, branches, fruits and grain. If the basic sugar molecule is that important to the whole equation of plant growth, it follows that if we can increase sugar production in plants it will have a major impact on plant production and quality.

Exciter is able to enter the plant cell due to its very small  molecular size. Although it doesn’t possess the quantity of nutrients normally expected of folair fertilizers, the nutrients it has are extremely efficient and effective, and are able to diffuse into the plants cells, providing energy and nourishment to the plant cell, which in turn then increases the level of sugar production as it photosynthesizes. Sodium molecules which are cations [positively charged molecules] make up a noticeable amount of the Exciter Super Ag Adjuvant product, and increase the plant’s electrical conductivity. In the chloroplasts of the cells’ sugar factory 4 positive magnesium molecules combine with 1 nitrogen molecule. These positive magnesium molecules help to attract and pull in the positive sodium molecules and other elements attached to the cation, getting a piggy back ride into the cells of the sugar factory. The net result of this is the availability of more fuel, energy and conductivity to boost the sugar making capacity of the sugar factory cells. Increased sugar levels in a variety of plants and the results are even more spectacular where normal plant nutrition is limiting or compromised.

When this higher sugar level [referred to as Brix] is achieved, plant production increases, also helping to boost what is termed systemic acquired resistance or SAR for short. With higher Sugar/Brix levels, the plant has an ability to defend itself from attacks by pests and pathogens, as a result of having a good supply of nutrients coupled with a high sugar level & Increased Carbon Dioxide Utilization.

The argument can be supported that is efficient at lowering greenhouse gas emissions by lowering carbon dioxide levels, as plants sprayed makes more sugar. As a final bonus, the use of lower carbon dioxide output and should be eligible to be traded for Carbon Credits, around the world.