Seed index system and methods for treating agricultural seeds with one or more seed care products employing a size-adjusted application rate based on the size of the seeds. Such size-adjusted application rates can be determined by a supplier of seed care products and communicated to an applicator who applies the seed care product to a quantity of seeds. Such size-adjusted application rates can be in the form of a chart, an equation, or a calculator.

Seed index system and methods for treating agricultural seeds with one or more seed care products employing a size-adjusted application rate based on the size of the seeds. Such size-adjusted application rates can be determined by a supplier of seed care products and communicated to an applicator who applies the seed care product to a quantity of seeds. Such size-adjusted application rates can be in the form of a chart, an equation, or a calculator.

The present invention refers to a device for the inoculation of seeds that is attached internally to a seed meter or a seed box on a planting machine. This is done to carry out the inoculation and treatment of seeds at the same time that they are being planted. The device has a reservoir where the inoculant is placed and then subsequently taken by the pump to the cylindrical mixture chamber. At the top of the cylindrical mixture chamber is a nozzle, which is located at the opposite side of where the seeds leave. They leave from the bottom of the device. There is a drive axle and a group of gears that move and give force to the blades that mix the seeds in the fluid located in the inner part of the chamber. The chamber is connected to the seed distributor disc and the flow of seeds is based on the seed distributor disc's consumption.

The present invention refers to a device for the inoculation of seeds that is attached internally to a seed meter or a seed box on a planting machine. This is done to carry out the inoculation and treatment of seeds at the same time that they are being planted. The device has a reservoir where the inoculant is placed and then subsequently taken by the pump to the cylindrical mixture chamber. At the top of the cylindrical mixture chamber is a nozzle, which is located at the opposite side of where the seeds leave. They leave from the bottom of the device. There is a drive axle and a group of gears that move and give force to the blades that mix the seeds in the fluid located in the inner part of the chamber. The chamber is connected to the seed distributor disc and the flow of seeds is based on the seed distributor disc's consumption.

Methods and apparatuses to activate, modify, and sanitize the surfaces of granular, powdered, or seed material placed in a continuous flow of a low-temperature, reduced-pressure gas plasma. Said plasma may be created with radio-frequency power, using capacitive-inductive, or a combination of both types of discharge. The plasma is generated at pressures in the 0.01 to 10 Torr range. RF frequency ranges from 0.2 to 220 MHz, and correspond to a plasma density between about n.sub.e10.sup.8-n.sub.e10.sup.12 or 0.001 to 0.4 W/cm.sup.3. Inserts and electrodes may be temperature controlled to control process conditions. RF discharge may be pulsed or modulated by different frequency in order to stimulate energy exchange between gas plasma and process material. The apparatuses may be grounded, biased and mechanically activated (e.g., vibration, rotation, etc.).

A rotary atomizer is disclosed for the even distribution of a treatment fluid within a treatment chamber. The treatment fluid is delivered onto a rotating disk atomizer through multiple outlet ports. Fluid passages provide each outlet port with an even flow of treatment fluid at generally the same time and rate. This even and simultaneous flow of treatment fluid results in a more even distribution of treatment fluid on the seed that flows through the treatment chamber throughout the treatment cycle.

A rotary atomizer is disclosed for the even distribution of a treatment fluid within a treatment chamber. The treatment fluid is delivered onto a rotating disk atomizer through multiple outlet ports. Fluid passages provide each outlet port with an even flow of treatment fluid at generally the same time and rate. This even and simultaneous flow of treatment fluid results in a more even distribution of treatment fluid on the seed that flows through the treatment chamber throughout the treatment cycle.

The invention relates to treatment of a plant with one or more microorganisms for inhibiting a plant pathogen. More particularly, the invention relates to isolated Bacillus strains, and strains having all of the identifying characteristics of these strains, and combinations thereof, for a use comprising the above-mentioned use.

Rapid pulse programming of a seed, to obtain improved germination probability, and increased root mass, and crop yield, by illuminating the seed with radiation of a wavelength distribution from 300 nm to 20 microns, with a minimum average irradiance of 0.2 Watts/cm.sup.2 and a maximum average irradiance of 7 Watts/cm.sup.2, and having a narrow specific range of cumulative illumination energy from Joules/cm.sup.2 to 3 Joules/cm2 or a higher transition point cumulative illumination energy, so as to specifically engage an irradiance-sensitive and energy-sensitive hidden stimulative exposure response in the seed and so as to avoid illumination of higher cumulative illumination energy that would cause a different and destructive exposure response in the seed. Preferred wavelengths include one or both of Medium Wavelength Infrared (MWIR) radiation and an Indigo Region Illumination Distribution (IRID), which may be applied to an illuminated agricultural planter.

Provided is a method for controlling arthropod pests. The method includes: step A): a step of forming furrows in the soil; step B): a step of placing, in the furrows formed in the previous step, seeds retaining one or more neonicotinoid compounds selected from Group I, on the surface or in the interior, and a step of applying an aqueous dispersion or an aqueous solution containing one or more neonicotinoid compounds selected from Group I to the furrows formed in the previous step; and step C): a step of covering the furrows. In step B above Group I is a group selected from clothianidin, thiamethoxam, imidacloprid, and thiacloprid.