Airborne mineral dust particles have potentially important influences on cloud and precipitation processes. Dust particles from deserts or semi-arid regions are one of the main sources of natural aerosol particles, and they have been implicated to play the role of ice nuclei which initiate cloud glaciation, and cloud condensation nuclei which initiate cloud drop formation. On the other hand, cloud processes may also have potentially important influences on airborne dust, such as influences dust deposition processes. Furthermore, dust deposition may provide micronutrient such as iron to the ocean and thus influences marine ecosystem. Therefore, this study is aimed to build up a comprehensive dust module to understand the interactions between dust and cloud, and also the input of dust iron into the ocean. The dust emission module was first coupled into the CMAQ (Community Multiscale Air Quality Modeling System) model to understand the input of dust into the ocean. The original empirical scavenge formula was replaced with the SNAP (Statistical-Numerical Aerosol Parameterization) scheme, which was derived from calculations based on the fundamental equations. Beside dust, fly ash is also an important source of iron in the East Asian region, so it is also considered in this study to understand their relative importance comparing to dust. Simulations for the 2007 conditions showed that the iron deposition from mineral dust constituted about 93% of the total iron deposition over the Northwestern Pacific Ocean and 85% of that over the Northern South China Sea. But when considering the much higher solubility of fly ash iron than dust iron, fly ash may have greater influence on the ecosystem over the marginal seas in East Asia. The CMAQ model applied earlier is a chemical transport model, which is useful for a long-term simulation of the long-term dust transportation and deposition, but its lack of coupled cloud processes makes it unsuitable for detailed study on the interactions between dust and cloud, such as the rainout processes. Therefore, a dust emission module was implemented into the WRF model and coupled with the cloud microphysics to understand the issue of dust-cloud interactions. The processes between dust and cloud considered in the model include heterogeneous ice nucleation, cloud drop activation, dust collection, and dry and wet depositions, and they were parameterized with the SNAP scheme. The simulated case is a cold-front leading dust event which caused muddy rain over northern Taiwan during 1st to 3rd of April, 2007. The sensitivity experiments showed that ignoring the dust effect on cloud may cause an underestimation of the cold cloud hydrometeor content and a slight reduction in precipitation (by about 3%). The main mechanisms involved are the heterogeneous ice nucleation processes, with deposition nucleation more important than the immersion freezing. On the other hand, ignored the dust in-cloud scavenging (rainout) process may overestimate total dust loading and surface dust concentration by about 87% and 5%, respectively; for the below-cloud scavenging (washout), the values become 5% and 1% only. This result indicates that the rainout processes, which were commonly ignored in earlier modeling studies, are much more important than the washout process.