Organic photovoltaics (OPVs) have advantages of low cost, structure designability, light weight and flexibilility. Therefore, many studies have focused on the development of new materials to enhance the power conversion efficiency and stability. In this thesis, we introduced electron-withdrawing cyano groups onto thieno[3,2-b]thiophene (TT) and synthesized three series of molecules as donor, acceptor and emitter material. In the first part, we used TT and TTCN as acceptor unit in a configuration of D-A-A type molecule and synthesized four molecules: DTCPTT, DTCPTT-2CN, DTDCPTT and DTDCPTT-2CN. The results showed the strategy can dramatically lower LUMO while slightly lowering HOMO, thus decreasing the energy gap. Overall, the device of DTDCPTT not only exhibited high PCE (up to 7.81%) under AM 1.5 G irradiation with Jsc of 13.56 mA/cm2, Voc of 0.86 V and FF of 67.81%, but also performed PCE over 16% under TLD-840 lamp, indicating its promising prospect for photovoltaic application. In the secondary part, we used different substituents onto A-D-A type molecules. One was introduced cyano groups to tune energy level, and the other was introduced alkoxy groups to redshift the absorption due to increased dipolar moment. The results showed that TTCN-DC and TTCN-RH, introducing cyano groups could lower LUMO to -3.68 eV to as acceptor, and TTOHex-DC and TTOHex-DC introducing alkoxy groups could redshift the absorption of 100 nm. Because of the matching energy level and complementary absorption, they were expected to achieve better PCE. In the third part, we introduced different numbers of cyano groups onto D-A-D type molecules, which influenced those material’s properties. Among those molecules, DDTCNTT with a cyano group has the best external quantum effect 3.52% in the case of dopant in exciplex-host.