This thesis seeks to develop a new aerosol parameterization scheme which not only can describe the chemical and physical processes of aerosols in detail but also enable the study of aerosol-cloud interactions and their impact on climate. The first effort is to incorporate a sulfur cycle into a coupled global climate-chemistry model and use it to estimate the direct and indirect radiative effects due to anthropogenic sulfate. Climate forcing from sulfate aerosols is analyzed by a set of simulations that turns of an off anthropogenic emissions, and turn on and off the direct effect and the first indirect effect. The results show that anthropogenic sulfate aerosols may produce a global direct forcing of about -0.32 W m-2, and indirect forcing of about -1.69 W m-2. The signals from the first indirect effect are larger than the internal climate variability of the model, but those from the direct effect are not. The first indirect effect not only influence surface temperature but also other climate parameters, such as cloud cover, precipitation and circulation pattern, on the global and regional scales. Concentrations of chemical species, including sulfate itself, also change somewhat due to the sulfate 1st indirect effect. This implies the aerosol-cloud interaction is important to climate and chemistry in both regional and global scales. The second part of this study is to develop an “Interactive Cloud-Aerosol Parameterization scheme” (ICAPs) that is suitable for application in regional and global models. This scheme applies the modal approach by describing the size distribution of each aerosol mode with three moments. Fundamental growth equations for the whole group of aerosols are integrated numerically for a wide range of conditions, and the results are analyzed and fitted into simple parameterization formulas that are functions of the three moments. The advantages of this scheme are (i) easy to use, (ii) separate out environment properties for better accuracy, (iii) provide solution when analytical solution is not available, and (iv) computational efficient. Besides the dynamic processes of aerosol evolution, diagnostic properties such as effective radius can be are also provide. This ICAPs is shown to perform well by comparing with analytical solutions and detailed bin models for either simple or complicated aerosol processes such as the Brownian coagulation. The ICAPs was applied into a box model and a regional air quality CMAQ, and showed good performance in aerosol processes against a traditional aerosol parameterization scheme. It is also applied into a regional mineral dust model (TAQM/kosa) and showed very good agreement with that calculated with a binned approach.. The CPU time saved for running TAQM/kosa with ICAPs instead of the binned approach is about 33%, while that saved for running CMAQ is about 18%.