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1) Physical adsorption and outgassing: The polymer surface physically adsorbs gases such as water vapor and oxygen from the air. In a vacuum environment, these gas molecules, bond by weak van der Waals forces, rapidly desorb and are released.

2) Volatilization and decomposition: The numerous additives and residual monomers in the polymer have relatively low molecular weights and high vapor pressures. Under vacuum and thermal stress conditions, they either volatilize directly or decompose into smaller gas molecules, which then escape.

In different applications, the released gas molecules may have multiple adverse effects on system performance:

• For airtight enclosures, such as the sealed cavities formed in T/R modules through parallel seam welding or laser welding, the gas molecules released by organic polymers cannot escape these enclosed spaces. Many of these gas molecules can damage the chips inside the cavity. For example, for a GaAs MMIC chip, exposure to only 0.5% hydrogen atmosphere can lead to significant device performance degradation after 500 hours.[1][2]
• For low-pressure or vacuum environments, such as satellite-borne equipment, the gas contained within organic polymers expands due to the reduced external pressure, generating substantial stress. In severe cases, this stress is likely to damage the chips. For instance, MIL-STD-883, Method 1001 specifies low-pressure test conditions to verify the ability to withstand pressure differentials. [3]
• For vacuum-packaged devices, gases released by organic polymers directly reduce the vacuum level, thereby affecting device performance.