This paper investigates the generation of an ultrawide spectrum in the mid-infrared region using a suspended-core fiber (SCF) fabricated from As₂Se₃ chalcogenide glass, in which carbon disulfide is employed as a liquid filling material for three air-holes instead of conventional air. The inclusion of carbon disulfide in the air pores significantly modifies the dispersion characteristics of the optical fiber, enabling a flattened dispersion profile close to zero over a broad wavelength range. Such dispersion-tuning techniques play a crucial role in enhancing nonlinear spectral broadening. Simulation results demonstrate that an ultrawide spectrum spanning from 0.99 μm to 3.925 μm can be generated in the proposed SCF, which is only 10 cm long, using a low peak power of 800 W with a pump pulse centered at 2500 nm. The smooth supercontinuum spectrum obtained in the all-normal dispersion regime is expected to exhibit high temporal coherence, as the spectral broadening is primarily influenced by deterministic nonlinear effects such as self-phase modulation and optical wave breaking.