Indirect coupling simulation method of microfluidic dielectrophoresis sorting chip

Abstract

The invention discloses an indirect coupling simulation method of a microfluidic dielectrophoresis sorting chip, and relates to the technical field of dielectrophoresis. The method comprises the following steps: establishing a phase field model in a multiphase flow; adopting a finite element method to obtain dielectrophoretic force which changes along with time and space and is borne by particles;inputting the dielectrophoresis force as an external force item into the phase field model in the multiphase flow, and solving the phase field model in the multiphase flow to realize indirect coupling; adopting a lattice Boltzmann method to calculate the phase field model in the multiphase flow, calculating electric field intensity distribution in a chip and track and characterize motion trails of the particles. The advantages of the finite element grid method for solving the electric field can be exerted, the advantages of the lattice Boltzmann method for solving micro-scale flow and flexible cell deformation can also be exerted, the chip structure can be optimized according to the simulation result, and a new thought is provided for design and manufacturing of the microfluidic dielectrophoresis chip.

Description

technical field

[0001] The invention relates to the technical field of dielectrophoresis, in particular to an indirect coupling simulation method of a microfluidic dielectrophoresis sorting chip. Background technique

[0002] Microfluidic chip technology integrates basic operating units such as sample preparation, pretreatment, reaction, separation, and detection in biological and chemical analysis processes into a micron-scale chip, which can realize the transportation and mixing of fluids, micro-nano particles, or droplets. , Sorting, enrichment, logic operations and other operations are of great strategic significance to the development of life sciences and information sciences. Under a non-uniform electric field, micro-nano-scale dielectric particles (such as polymer particles, various cells, bacteria, viruses, DNA, droplets, etc.) The strongest or weakest regions are clustered, respectively called dielectric positive.

[0003] The separation of biological particles (s...

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