At the start of the 21st century, energy issues have been paid attention year by year, as a potential solution for saving energy, thermoelectric materials have attracted a lot of study in the past 20 years. Among thermoelectric materials, Bi2Te3, because its maximum ZT value falls between 300 and 500 K makes it a high application potential near the room temperature range. Therefore, we are interested in if the Bi2Te3-based materials can be tuned to even improved advance. This work focused on the n-type materials Bi1.7Sb0.3Te2.7Se0.3, looking for n-type alloy bulk materials with high thermoelectric conversion efficiency by doping level tuning of Sb and Te (Sb: 0.05-0.1, Te: 15-30wt%). Meanwhile, three synthesize methods Bridgeman-Stockbarger Method, Furnace melting, spark plasma sintering (SPS) are employed to study the influence of the method on the ZT values and effects on thermoelectric properties. The prepared samples are analyzed by X-ray diffractometer (XRD) and X-ray fluorescence analyzer (XRF) for identification of crystalline phases and the atomic ratio. The ZEM-3 and LFA are employed to study the electrical conductivity and Seebeck coefficient, and thermal conductivity, respectively. Taking the Bi1.75Sb0.25Te2.7Se0.3 sample that is prepared by the pre-melting method as a reference, the material figure of merit ZT is about 0.55. While the maxima ZTs of Bi1.75Sb0.25Te2.7Se0.3+15wt%Te that prepped by the Bridgman method (growth rate of 5 mm/hr at 750 degrees) and by the spark plasma sintering system (at 380 degrees 50 MPa) are reached up to 0.84 and 0.8, respectively. Which are significantly higher than that of the Bi1.75Sb0.25Te2.7Se0.3. However, the zT suppressed at high tuning level, which indicates that the Te tuning shall not higher than 20wt%.