Germanium is considered as one of the promising channel materials owing to its higher bulk carrier mobility than silicon. However, germanium sub-oxide is thermodynamically unstable. GeO volatilization will degrade the interface and impact the electric characteristics. Therefore, the effect of various thermal processes on germanium metal-insulator-semiconductor capacitor quality are studied in this thesis. First, applying various pre-gate thermal treatments on germanium capacitor are discussed. We can find that increasing germanium oxide with more amount of high oxidation states and less amount of low oxidation states can get better interface quality. Both densification and surface annealing will increase oxidation states of germanium differently. Densification before active area patterning will generate germanium oxides and germanium compounds at the interface simultaneously. On the other hands, surface annealing in vacuum can desorb germanium oxides more and passivate surface better than surface annealing in N2 ambient. Thus, using surface annealing in N2 ambient after densification cannot desorb the germanium compounds completely but surface annealing in vacuum after densification can desorb and passivate germanium surface effectively. After complete desorption, O2 plasma can form more amount of high oxidation state in following process. Compared with leakage current density and interface state density, it is suspected that combining densification in N2 ambient and surface annealing in vacuum is better than other pre-gate treatments. Second, the effects of gate stack formation and deposition temperatures are investigated. According to XPS analysis and electrical characteristics, there might have two possible mechanisms in GeO volatilization: GeO volatilization during deposition, and GeO volatilization during PDA and sintering. Therefore, it is suspected that higher temperature of plasma oxidation can help germanium oxide formation and lower temperature of deposition can decrease GeO volatilization during the deposition process. This method can remain more amount of germanium oxide at the interface and achieve lower interface state density and leakage current density. Third, the effect of PDA temperature on HfO2 and ZrO2 samples are discussed. Increasing the PDA temperature will make GeO volatilized and diffused into high-k film more. It will make ZrO2 partially crystalized and increase the k-value. Besides, we find ZrO2 sample has thicker interfacial layer than HfO2 sample at same PDA temperature. It is suspected that germanium might be oxidized more at the same PDA temperature on the ZrO2 sample. Finally, the better process conditions of previous thermal treatments are combined to fabricate the optimized device. By increase the amount of high oxidation states, the capacitor with EOT about 0.8 nm, low leakage current density of 1.5×10-2 A/cm2 at |Vg –VFB|=1 V, small hysteresis (~155 mV), low interface state density of 9.27×1011 eV-1cm−2 at E− EV = 0.2 eV has achieved in this thesis. We expected these achievements can be applied to improve the performance of Ge MOSFETs.