A method for the management of a soil pest or pathogen is disclosed and which includes a source of high voltage electricity; at least one capacitor for storing the high voltage electricity; a multiplicity of electrodes inserted into a soil location having a soil pest and/or pathogen to be managed; and an electrical switch which is controllably opened and closes so as to form a pulse of electricity which is passed through the soil location and between the electrodes so as to effect the management of the soil pest and/or pathogen

An apparatus for using microwave energy for treating an infected site infested with insects or other small pests is disclosed. The apparatus comprises a source of microwave energy connected to a power source and a power controller, a transmission element, and an antenna. The apparatus can also comprise an isolator to protect the source of microwave energy. Methods to use such an apparatus for treatment of an infected site are also disclosed.

An electric device for killing insects and animals having a mesh surface holding assembly having at least one a conductive mesh surface, an electrical power source for providing electricity to the mesh surface, at least one light source constructed and positioned to provide backlighting on the mesh surface, an actuator for selectively initiating and ceasing supply of electrical power from the electrical source to the mesh by incorporated circuitry, and a handle assembly supporting the mesh surface assembly.

An apparatus for using microwave energy for treating an infected site infested with insects or other small pests is disclosed. The apparatus comprises a source of microwave energy connected to a power source and a power controller, a transmission element, and an antenna. The apparatus can also comprise an isolator to protect the source of microwave energy. Methods to use such an apparatus for treatment of an infected site are also disclosed.

An apparatus for using microwave energy for treating an infected site infested with insects or other small pests is disclosed. The apparatus comprises a source of microwave energy connected to a power source and a power controller, a transmission element, and an antenna. The apparatus can also comprise an isolator to protect the source of microwave energy. Methods to use such an apparatus for treatment of an infected site are also disclosed.

A method to evaporate active ingredients from a liquid solution, in which said liquid solution includes a solvent and at least one type of active ingredient, the method including dispensing in controlled time periods doses of said liquid solution on a liquid retaining support, where the solvent is evaporated from the support such that only the active ingredient remains on the support, and where the active ingredient is evaporated from the support after most of the solvent has evaporated.

An underwater device for subduing underwater invasive species includes a translucent or transparent fixture having a TiO2 coating on at least one side of the fixture and a light source positioned to expose the coating with light having sufficient intensity and selected range of frequencies to activate the photocatalytic TiO2 coated fixture.

An underwater device for subduing underwater invasive species includes a translucent or transparent fixture having a TiO2 coating on at least one side of the fixture and a light source positioned to expose the coating with light having sufficient intensity and selected range of frequencies to activate the photocatalytic TiO2 coated fixture.

The present invention is related to a method for improving plant growth and reduce the effects of diseases, with environmental friendly techniques. This is a method for controlling or ending diseases and also, to perform a non-stop electromagnetic combine with invaded electrons treatment with its effective methods for soil, plants, trees and their roots region. Furthermore, high voltage electricity can control the borer insect/s, nematodes in plant, tree and in the soil under treatment. Some of the pathogens, nematodes and insect/s in the region influenced by the magnetic field, invaded by squall of electrons, can be decontaminated after the treatment. The exited and invasive electrons pass through the magnetic field region via negative terminal and will be discharged at positive discharge points which located on discharge bar. After receiving the high voltage treatment, the infected plant can be stimulated to regenerate and grow new leaves, shoots, and/or flashes that exhibit little to no symptoms of infection, depending on the voltage applied to the infected plant and the condition of the infected plant.

A shocking cooler includes an ice chest cooler which has a lid and lower portion. A first conductor is located within the bottom portion and extrudes from one of the side interior surfaces of the ice chest cooler. A second conductor is located near a lower lip region, and is separated a distance from the first conductor. The first conductor and second conductor are joined to a power supply at alternate connections (either positive (+) or negative ()) by connection cable(s). The power supply is connected to a switch, which allows the shocking ice chest cooler to be turned on or off. Water is introduced to the ice chest cooler, and is in contact with the first conductor. When a burglar attempts to reach into the ice chest cooler, his hand is immersed into the water, thereby completing the circuit and issuing an electrical shock.