Boron nitride (BN) has good thermal conductive capacities and cheap price, so BN becomes common filler inorganic materials for heat dissipation in the industrial applications. We got some good results from our present project in the past half an year, i.e., “Enhancements of Thermal Conductivities in Polymeric Nano-Composites by Doping Boron Nitride (BN)”. The thermal conductivities of the polymeric composites were enhanced gradually (up to 0.8 W / mK) as BN was added gradually in the polymers (RTV). In addition, the crystallinity of BN in the polymers was increased as the additive (1,8-diiodooctane) was introduced in the polymeric composites, and the XRD patterns prove the crystallinity of BN is proportional to the amounts of 1,8-diiodooctane. Thus, the thermal conductivities of the polymeric composites were improved due to the higher crystallinity of BN induced by the additive (1,8-diiodooctane). In this proposal, we focus on two different inorganic materials (boron nitride BN and aluminum nitride AlN with excellent thermal conductivities) blended with three different kinds of monomers containing various functional groups (including acrylic group, and C=C combined with Si-H groups). Different types and ratios of inoganic materials (boron nitride and aluminum nitride with various sizes) and polymers (containing acrylic group, and C=C, Si-H) were blended to produce various polymeric composites. Therefore, according to the adjustment of previous parameters, polymeric composites can be optimized to possess many different requested merits, such as packaging, thermal conductivity, thermal stress, and transparency, via the following characterization techniques: Thermal conductive equipments. Finally, we expect to obtain polymeric composites with the optimized thermal conductivities, thermal stress, transparency, and mechanical properties. Key Words: Polymer Composites, Hexagonal Boron Nitride, Aluminum Nitride, Heat Dissipation.