摘要
This work derives a unified description of a solution-particle using movement rate of component vibrations (strings). Projected Pharmacokinetic and Pharmacodynamic data from a patient on Efavirenz are used. Differential equations are used to formulate a system that governs a solution-particle field. A reconnaissance (frame) wave that envelops a solution-particle is derived. Its conductivity and diffusivity fluxes are found. The movement of the reconnaissance wave is found to be faster than diffusion and pilot waves. A solution-particle is accompanied by the three waves, diffusion, pilot and the frame and is active only at the boundary of space and time.
This work derives a unified description of a solution-particle using movement rate of component vibrations (strings). Projected Pharmacokinetic and Pharmacodynamic data from a patient on Efavirenz are used. Differential equations are used to formulate a system that governs a solution-particle field. A reconnaissance (frame) wave that envelops a solution-particle is derived. Its conductivity and diffusivity fluxes are found. The movement of the reconnaissance wave is found to be faster than diffusion and pilot waves. A solution-particle is accompanied by the three waves, diffusion, pilot and the frame and is active only at the boundary of space and time.
