Fig. 1. Mixed aerosol particle models of black carbon and non-absorbent aerosol under different mixing modes. (a) Internal mixing Core-shell model; (b) internal mixing Maxwell-Garnett model

Fig. 2. Relationship between extinction coefficient and volume ratio of black carbon and non-absorbent aerosols under Maxwell-Garnett mixing model

Fig. 3. Relationship between extinction coefficient and volume ratio of black carbon and non-absorbent aerosols under Core-shell mixing model

Fig. 4. Relationship among link attenuation, black carbon volume ratio, and transmission distance of black carbon and sulfate aerosol under Maxwell-Garnett mixing model

Fig. 5. Relationship among link attenuation, black carbon volume ratio, and transmission distance of black carbon and sulfate aerosol under Core-shell mixing model

Fig. 6. Relationship among double Pauli channel fidelity, black carbon volume ratio, and channel correlation factor of black carbon and sulfate aerosol under Maxwell-Garnett mixing model

Fig. 7. Relationship among double Pauli channel fidelity, black carbon volume ratio, and channel correlation factor of black carbon and sulfate aerosol under Core-shell mixing model

Fig. 8. Relationship among correlation bit reversal channel fidelity, black carbon volume ratio, and channel correlation factor of black carbon and sulfate aerosol under Maxwell-Garnett mixed model

Fig. 9. Relationship among correlation bit reversal channel fidelity, black carbon volume ratio, and channel correlation factor of black carbon and sulfate aerosol under Core-shell mixed model

Fig. 10. Relationship among quantum security key generation rate, black carbon volume ratio, and transmission distance of black carbon and sulfate aerosol under Maxwell-Garnett mixed model

Fig. 11. Relationship among quantum security key generation rate, black carbon volume ratio, and transmission distance of black carbon and sulfate aerosol under Core-shell mixing model