Indium gallium zinc oxide (InGaZnO) is commonly used as a channel layer thin film transistors (TFT) owing to its low temperature processability, superior mobility, and low leakage current. However, its thermoelectric (TE) properties are relatively less-explored. In this study, the TE performance of a typical InGaZnO TFT with SiO₂ gate insulator is investigated. Bottom-gate top-contact TE-TFTs were fabricated on p-type Si gate electrode with 85 nm of thermally oxidized SiO₂ layer as the gate insulator. The InGaZnO channel (70 nm) was deposited via RF magnetron sputtering at room temperature. Next, a metal thin film layer (80 nm Ti/20 nm Au) was deposited via electron beam evaporation. The channel islands, as well as the source and drain electrodes were patterned by standard photolithography. Finally, the fabricated devices were post-annealed at 300°C for 2h under air. To measure the Seebeck coefficient (S), the method by Liang, et. al was adopted. The InGaZnO TE-TFT exhibit proper switching, with a μ = 10.4 cmV^-1S^-1. This suggests typical transistor behavior, even at a low V_D of 100 μV, where the Seebeck voltage is expected to range. Similarly, the PF exhibits a switching behavior under positive V_G, with a maximum of ~0.1 mW/mK² at V_G = 40 V. This superior PF can mostly be attributed to the σ increasing by two orders of magnitude, while maintaining a decrease in S to only ~35%. This suggests a possible suppression of the coupling reaction of S and σ, owing to the electron confinement at the extremely narrow accumulation layer formed at the InGaZnO/SiO₂ interface.