Three-dimensional topological insulators like Bi2Se3 exhibit spin-polarized surface states which the spin of electron is locked to their momentum[1, 2]. The circular photogalvanic effect (CPGE) is an optical approach to investigate the helical surface states by utilizing circularly polarized light to generate spin photocurrent in three-dimensional topological insulators[3]. In this work, the thermal solid method is used to deposit Bi2Se3 thin films on sapphire substrates. The lattice structure and binding energy of the material are investigated by XRD and XPS measurements which show high-quality single crystal formation and highly coherent covalent bonding. The conduction behavior of carriers in Bi2Se3-based top gate MOSFETs is studied, revealing ambipolar behavior consistent with tuning between electrons and hole carriers within the thin film. The CPGE of the three-dimensional topological insulator Bi2Se3 is investigated by applying DC bias and gate voltage individually at room temperature. It is found that the photocurrent from CPGE and linear photogalvanic effect (LPGE) can be clearly demonstrated for Bi2Se3, even at room temperature, despite the existence of bulk carriers. Different DC biases are applied, and the longitudinal electric field affects the population of electrons in momentum space, resulting in different photocurrents from left and right circularly polarized light excitation. The photocurrent variation with gate voltage is also investigated, where the Fermi level is tuned, leading to changes in the population of bulk state carriers and spin electrons in surface states. Our work showed the helical spin polarized photocurrent of Bi2Se3 can be manipulated by electric field at room temperature.