Phases in condensed matters, such as superconductivity (SC), spin density wave (SDW), charge density wave (CDW) and etc, normally arises from the instability of the Fermi surface and are tied up with the topology of Fermi surface. It is therefore not clear when the energy band involved is dispersionless, i.e., a flat band, how different phases may arise in the presence of interaction. An interesting example is the surprising SC that is recently found at flat-bands of a magic-angle twisted bilayer graphene. In this thesis, we explore how condensed matter phases arise in a flat band in a Lieb lattice. By resorting to the renormalized mean field theory (RMFT), we analyze the t-J model on the Lieb lattice. We compute allowed phases self-consistently in the real space as well as in the momentum space and found consistent numerical results from these two spaces. The global phase diagram is constructed. Our results indicate that due to being an imbalanced bipartite for the Lieb lattice, two uniform SC phases with different pairing symmetries that are in coexistence with the ferrimagnetic order arise at the low doping regime. When doping increases, SDW and CDW emerge and coexist with the ferrimagnetic phase. These condensed matter phases provide useful hints on how condensed matter phases are adapted to systems with flat bands.