We report a study on epitaxial BiFeO3 thin films on LaAlO3 substrates with focuses on their structural nature, thermodynamic stability and ferro-/piezoelectric properties. First, we use Reciprocal space maps (RSM) to confirm the structure symmetry of BFO thin film at different temperature. Then, we use temperature-variable piezoelectric force microscopy (PFM) and observed a rotational transition of in-plane ferroelectric polarization (IPP-PFM) and piezoelectric coefficient (d33). Form RSM data, we found the dominant phase at room temperature possess an MC symmetry (a = 3.81 Å, b = 3.76 Å, c = 4.64 Å, βMC = 88.5° ) but switches to an MA symmetry (a = 3.80 Å, b = 3.79 Å, c = 4.66 Å, βMA = 86.8°) at 150oC . Furthermore, IPP-PFM images reveal that temperature of BFO thin film will affect a rotational transition of in-plane ferroelectric polarization from [100] to [110]. Also, in stable phase of either MC or MA have a steady d33 around 50 or 60 pm/V, but at 150 oC, a significant increase in d33 to 98.1 pm/V is observe. This phenomenon can be understood as both the lattice structure and ferroelectric polarization additional degrees of freedom to respond to the external electrical field. In summary, the symmetry structure change is accompanied by a ferroelectric polarization rotation, and the piezoelectric response is also enhanced considerably at the same temperature. These results provide key insights into the ferroelectric materials and could help future engineering of highly piezoelectric thin films.