Abstract
Abstract Communication blackouts during atmospheric reentry pose significant challenges to the safety and adaptability of spacecraft missions. 
This phenomenon, caused by the attenuation of electromagnetic waves by the plasma surrounding the spacecraft, disrupts communication with ground stations or orbiting satellites.
Therefore, it is crucial to decrease the plasma density in the vicinity of the spacecraft to ensure an unobstructed electromagnetic wave communication path.
This study proposes a methodology that involves the injection of gas from the vehicle's wall to create an insulating layer near the surface. 
This thin layer maintains lower temperatures and reduced plasma density, enabling electromagnetic wave propagation without attenuation. 
Practical experiments were conducted in an arc-heating facility to simulate atmospheric reentry conditions.
The results of the experiments provided empirical evidence of the effectiveness of the technique in mitigating communication blackout phenomena.
Numerical fluid analysis within the wind tunnel chamber validated the formation of an air film layer near the experimental model owing to the injected gas. 
Schlieren imaging revealed distinctive jet shapes, which corroborated the findings of the numerical analysis. 
The wind tunnel tests that simulated atmospheric reentry environments confirmed the formation of an air film layer through gas injection, which substantiates the reduction in communication blackout.
These results have the potential to improve communication reliability in space transport.
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