Hybrid Scattering-Based Modeling and Performance Analysis of 6G Sub-THz Backhaul in Severe Dust Stormsdoi:10.7910/DVN/YQ7AURHarvard Dataverse2026-04-051Al-barazanchi, Karrar Sameer Khudhair, 2026, "Hybrid Scattering-Based Modeling and Performance Analysis of 6G Sub-THz Backhaul in Severe Dust Storms", https://doi.org/10.7910/DVN/YQ7AUR, Harvard Dataverse, V1Hybrid Scattering-Based Modeling and Performance Analysis of 6G Sub-THz Backhaul in Severe Dust Stormsdoi:10.7910/DVN/YQ7AURAl-barazanchi, Karrar Sameer KhudhairAl-barazanchi, Karrar Sameer KhudhairHarvard DataverseAl-barazanchi, Karrar Sameer KhudhairAl-barazanchi, Karrar Sameer Khudhair2026-04-04EngineeringA hybrid electromagnetic scattering model implemented in Octave/MATLAB that computes dust-induced signal attenuation across the 90–300 GHz sub-terahertz band by integrating Rayleigh, Mie, and Anomalous Diffraction Theory within a Maxwell-Garnett dielectric mixing framework. The model evaluates end-to-end 6G link performance metrics, including SNR, capacity, BER, latency, and link margin across visibility conditions ranging from clear haze to severe desert dust storms.<a href="http://creativecommons.org/publicdomain/zero/1.0">CC0 1.0</a>The_Model.mA hybrid electromagnetic scattering model implemented in Octave/MATLAB that computes dust-induced signal attenuation across the 90–300 GHz sub-terahertz band by integrating Rayleigh, Mie, and Anomalous Diffraction Theory within a Maxwell-Garnett dielectric mixing framework. The model evaluates end-to-end 6G link performance metrics, including SNR, capacity, BER, latency, and link margin across visibility conditions ranging from clear haze to severe desert dust storms.text/plain