With growing environmental awareness, organic photovoltaic (OPV) devices have been highly developed lately owing to being clean energy source, low-cost manufacture, and roll-to-roll solution production. Interlayer plays an important role on promoting the device performance including enhanced light-conversion efficiency as well as extended lifetime. However, renewable materials are only slightly explored as an interlayer in OPV. By further understanding the underlying mechanisms of interlayer, bio-based materials and green process are explored to fabricate an eco-friendly OPV in this thesis, including alcohol block copolymers and bio-based poly-lysine. In chapter 2, a series of alcohol-soluble cross-linked block copolymers (BCPs) poly(nBA)n b poly(NVTri)m (named as PBAn-Trim), consisted of poly(n-butyl acrylate) (poly-(nBA)) and poly(N-vinyl-1,2,4-triazole) (poly(NVTri)) blocks were prepared and served as the electron-extraction layer (EEL) in OPVs. After taking the crosslinking reaction, the ionic functionality was largely increased by forming a triazolium cation forming more effective interfacial dipoles to adjust its WF, and the structural robustness was able to be further rectified. The PBA70-Tri30 based OPV device improved by almost four times for power conversion efficiency (PCE) and more than 80% of its initial performance was retained after being heated at 60 °C for 1000 h or exposed under continuous illumination (1 sun) for 1000 h. It suggests that PBAn-Trim is a green processing EEL of high performance OPVs with superior thermal stability and photostability. In chapter 3, bio-based poly-lysine and its enantiomers were employed as EELs in OPVs to verify their work function (WF)-tuning capabilities, including poly-L-lysine and poly-L-lysine blend poly-D-lysine. These two poly-lysine groups, with different arrangements of the amino groups that built up different surface dipoles, altered the surface energy and WF of indium tin oxide (ITO). Poly-L-lysine possessed intense ionic functionality, revealing well capability to form effective interfacial dipoles interface to facilitate the charge transport at the corresponding interface. The WF-tuning functions lied strongly in the polarity increase and thus poly-L-lysine was discovered to be an efficient green interlayer presenting a high increase of 4.7 times in PCE. In chapter 4, the green poly-lysine was further applied as an interfacial layer (IFL) of EEL and the subsequent morphology evolution of active layers was studied for enhanced efficiency and stability in OPVs. By embedding poly-lysine as IFL, it not only observed the changes of the blend film phase segregation but also enhanced the molecular packing in the preferential face-on orientation. The optimized blend film morphology facilitated the carrier extraction, thereby significantly enhanced the OPV performance with the best PCE of 12.5% and 15.3% for the PBDB-T-2Cl:IT-4F and PBDB-T-2F:Y6 blends, respectively. Moreover, the poly-lysine on changing BHJ morphologies also greatly improved thermal- and photo-stability. Besides, poly-lysine could be used to fabricate a flexible OPV on renewable polyethylene furandicarboxylate (PEF) substrate. It was proved the general applicability of poly-lysine film, besides the bio-based IFL and substrate were successfully incorporated to develop flexible OPV showing great environmentally friendly potential. In summary, the green solvent processable block copolymer and bio-resourced polymers were successfully employed as the interlayer to tune the work function or morphology, which led to high performance OPVs for sustainable development.