Behavior of Ultrafine Particles in Electro-Hydrodynamic Flow Induced by Corona Discharge
Ravi Sankar Vaddi, Yifei Guan, Igor Novosselov

TL;DR
This study combines experimental and numerical methods to analyze ultrafine particle behavior in electro-hydrodynamic flows induced by corona discharge, revealing how particle size and charge affect transmission and flow dynamics.
Contribution
It introduces a coupled multiphysics model for EHD flow and particle transmission, providing new insights into nanoparticle charging and transport in corona discharge environments.
Findings
Velocity ranges from 1 to 4 m/s depending on corona voltage.
Particle transmission varies with size, especially below 20 nm due to charging effects.
Numerical results agree well with experimental velocity profiles.
Abstract
Ultrafine particle behavior in electro-hydrodynamic (EHD) flow induced by corona discharge is studied experimentally and numerically. The EHD flow serves as a primary particle aspiration/sampling mechanism, the collector does not require any additional flow generation. Multiphysics numerical model couples the ion transport equation and the Navier-Stokes equations (NSE) to solve for the spatiotemporal distribution of electric field, charge density, and flow field, the results are compared with experimental velocity profiles at the exit. The computed velocity and flow rate data are in good agreement with the experimental data; the maximum velocity is located at the axis and ranges from 1 m/s to 4 m/s as a function of corona voltage. Experimentally evaluated particle transmission trends for ambient and NaCl nanoparticles particles in the 20 nm - 150 nm range are in good agreement with the…
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