Multiscale modeling strategy and general theory of non-equilibrium plasma assisted ignition and combustion
Suo Yang, Wenting Sun, Vigor Yang

TL;DR
This paper presents a comprehensive multiscale theoretical framework for plasma-assisted ignition and combustion, incorporating a novel modeling approach and a general theory dividing the process into four distinct stages.
Contribution
It introduces a self-consistent 1D modeling framework with a frozen electric field approach, dynamic chemistry acceleration, and a multitimescale strategy, along with a general theory of plasma discharges in ignition.
Findings
The four stages of nanosecond pulsed plasma discharges are characterized by distinct timescales and mechanisms.
The framework effectively captures energy coupling, radical generation, and gas heating processes across stages.
Plasma significantly enhances radical production and preheating, promoting autoignition in flames.
Abstract
A selfconsistent 1D theoretical framework for plasma assisted ignition and combustion is reviewed. In this framework, a frozen electric field modeling approach is applied to take advantage of the quasiperiodic behaviors of the electrical characteristics to avoid the recalculation of electric field for each pulse. The correlated dynamic adaptive chemistry (CoDAC) method is employed to accelerate the calculation of large and stiff chemical mechanisms. The timestep is updated dynamically during the simulation through a three-stage multitimescale modeling strategy, which takes advantage of the large separation of timescales in nanosecond pulsed plasma discharges. A general theory of plasma assisted ignition and combustion is then proposed. Nanosecond pulsed plasma discharges for ignition and combustion can be divided into four stages. Stage I is the discharge pulse, with timescales of O(1…
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