Over the years, the global demand for energy and the concerns of environmental issues have been driving scientists to develop renewable and sustainable energy resources. Photovoltaic technologies, which directly convert sunlight into electricity, are regarded as one of the most promising strategies to meet the requirements. Organic photovoltaics (OPVs) have attracted much attention from scientific community because of their potential advantages such as cost-effective fabrication, light weight and mechanical flexibility, and low environmental impact production which make them as alternative to the conventional silicon-based solar cells. The objective of this dissertation was the preparation of small-molecule and polymeric materials comprised of coplanar multi-fused pi-cores for application in organic solar cells (OSCs), with the focus on the discussion of chemical structure-fundamental properties-device performance correlations. Chapter 1 describes a brief introduction of OPVs and emphasizes design principles for photoactive materials. Chapter 2 presents small-molecule donor materials containing rigid pi-moieties with different molecular framework for use in vacuum-deposited OSCs. Their synthesis, optoelectronic properties and solar cell device performance are discussed. Chapter 3 comprises the synthesis and characterization of symmetric small-molecule donor materials with coplanar pi-units for solution-processed OSCs. Chapter 4 includes the design, synthesis and optoelectronic characterization of p-type and n-type polymeric materials based on multi-fused ring structures for solution-processed OSCs. These research efforts have elucidated the structure-property-performance relationship and contributed to the development of conjugated materials for high-performance OSCs.