A system and method of scheduling tasks, comprising receiving activity and performance data from registers or storage locations maintained by hardware and an operating system; storing calibration coefficients associated with the activity and performance data; computing an energy dissipation rate based on at least the activity and performance data; and scheduling tasks under the operating system based on the computed energy dissipation rate.

Systems and methods for cryogenic separation of plant material are provided. A vessel is filled with cryogenic fluid having a temperature at or less than 150 degrees Celsius. Plant material is placed into the vessel via a basket and agitation is provided to the plant material in the vessel for a predetermined time period. Upon completion of the time period, the basket having at least a portion of the plant material is removed from the vessel. Plant particulates separated from the plant material during the agitation settle to the bottom of the vessel. The vessel is drained of the cryogenic fluid, including plant particulates separated from the plant material.

Systems and methods for cryogenic separation of plant material are provided. A vessel is filled with cryogenic fluid having a temperature at or less than 150 degrees Celsius. Plant material is placed into the vessel via a basket and agitation is provided to the plant material in the vessel for a predetermined time period. Upon completion of the time period, the basket having at least a portion of the plant material is removed from the vessel. Plant particulates separated from the plant material during the agitation settle to the bottom of the vessel. The vessel is drained of the cryogenic fluid, including plant particulates separated from the plant material.

The present disclosure describes a method of separating particles using a combination of acoustophoresis and acoustic fluid relocation. The disclosure also describes a microfluidic device that can be used to separate particles using a combination of acoustophoresis and acoustic fluid relocation. The disclosure describes methods of separating nanoparticles, microparticles, nanoparticles from microparticles, and micron-sized particles from sub-micron-sized particles.

The present disclosure describes a method of separating particles using a combination of acoustophoresis and acoustic fluid relocation. The disclosure also describes a microfluidic device that can be used to separate particles using a combination of acoustophoresis and acoustic fluid relocation. The disclosure describes methods of separating nanoparticles, microparticles, nanoparticles from microparticles, and micron-sized particles from sub-micron-sized particles.

System and method for cryogenic separation of plant material are provided. A vessel is filled with cryogenic fluid having a temperature at or less than 150 degrees Celsius. Plant material is placed into the vessel via a basket and agitation is provided to the plant material in the vessel for a predetermined time period. Upon completion of the time period, the basket having at least a portion of the plant material is removed from the vessel. Plant particulates separated from the plant material during the agitation settle to the bottom of the vessel. The vessel is drained of the cryogenic fluid, including plant particulates separated from the plant material.

System and method for cryogenic separation of plant material are provided. A vessel is filled with cryogenic fluid having a temperature at or less than 150 degrees Celsius. Plant material is placed into the vessel via a basket and agitation is provided to the plant material in the vessel for a predetermined time period. Upon completion of the time period, the basket having at least a portion of the plant material is removed from the vessel. Plant particulates separated from the plant material during the agitation settle to the bottom of the vessel. The vessel is drained of the cryogenic fluid, including plant particulates separated from the plant material.

A soil washing process includes mixing water and contaminated soil in a log washer, separating the soil and water mixture into a first stream of wet soil and a second stream of water and floating organic materials, dewatering the first stream of wet soil to form a cleaned soil stream, dewatering the second stream to separate out the organic materials and form a water stream, separating the water stream into a stream of non-colloidal particulates and a stream of colloid-containing water, dewatering the stream of non-colloidal particulates, and adding the stream of colloid-containing water to the soil and water mixture. The method may further include returning a first portion of the colloid-containing water to the log washer, and drawing off a second portion of the colloid-containing water to filter out the colloids before returning a clean water stream to the log washer.

A process for trichome separation from plant matter deploys an ionic brine to induce oedemic transformation of disk cell to aid in releasing glandular trichomes. The brine can be agitated to further release disk cells from the plant tissue. The disk cell debris can be separated by sieving the larger trichomes and plant tissue particles that results from agitation and maceration. If the brine concentration is appropriately modified, the trichomes will float and the brine and the plant tissue fragments sink. The floating trichomes are then removed and rinsed and then dried or extracted further after drying.

A system and method of scheduling tasks, comprising receiving activity and performance data from registers or storage locations maintained by hardware and an operating system; storing calibration coefficients associated with the activity and performance data; computing an energy dissipation rate based on at least the activity and performance data; and scheduling tasks under the operating system based on the computed energy dissipation rate.