In this dissertation, we have investigated the feasibility in using Ge as channel material of CMOS devices, including gate stacks, hetero-epitaxial Ge on Si substrate, and advanced device structure. Various high-κ gate stacks on Ge substrates have been demonstrated and studied by evaluating the interface quality of capacitors and device characteristics. Firstly, high-κ/Ge capacitors were performed with an ultra-thin GeO2 interfacial layer to improve the interface quality. The GeO2 layer ,which was grown by thermal oxidation, could effectively suppress the interface state density, and the Dit could be effectively reduced after forming gas annealing, with value about 5×1011 cm-2eV-1 near the midgap from either conductance or Fermi-level efficiency method. By extrapolation of versus , the determined σn and σp were about 2.7 – 4.2 × 10-16 and 7.8 – 9.6 × 10-16 cm2, respectively. By low temperature measurement, the Dit near band edge could be successfully extracted, and weak inversion response was also suppressed near midgap. Therefore, a normal U-shaped Dit distribution of Al2O3/GeO2 gate stack was revealed. With the experiences of integrating high-κ dielectric on the Ge substrate, Ge p-MOSFETs with the gate stack were successively fabricated by gate-last scheme. The high-field mobility of the MOSFETs with and without GeO2 passivation was 1.7 and 1.3 times higher than the Si universal curve, respectively. Also, better on/off ratio (3.3 orders) and subthreshold swing (170 mV/dec) were attained after FGA, resulted from lower reverse bias junction leakage and better interface quality. A gate stack with lower EOT, HfO2/Al2O3/GeOx, was subsequently demonstrated. A thin GeOx interfacial layer beneath an ALD-Al2O3 layer was performed by using post deposition oxidation method. Accompanying with HfO2 dielectric and relatively thin GeOx passivation layer, the EOT value was scaled down to 1.6 nm for the sample with PDO at 520 °C for 3 min and PDA in N2 ambient, and the Dit extracted from conductance method was about 1.5~5×1012 cm-2eV-1 near midgap. Through XPS analysis, less interface state density was due to that the thicker GeOx interfacial layer and larger Ge3+ peak improved the interface quality. Interface state density was shown to be reduced to 1.1~2.5×1012 cm-2eV-1 after forming gas annealing at 300 °C for 30 min, and positive VFB shift and lower C-V hysteresis was also obtained after FGA. Ge MOSFETs with HfO2/Al2O3/GeOx gate stack were fabricated by the gate-last scheme. The effect of forming gas annealing on the device characteristics was discussed. Consistent with the results of MOSCaps, the subthreshold swing was improved to 165 and 151 mV/dec for p-FET and n-FET after FGA, respectively. Even though the series resistance for both devices was increased, the driving current was improved because of the improvement in the interfacial quality and resultant higher carrier mobility. However, due to the fact that the n-type dopants easily out-diffused during thermal annealing and Fermi-level pinning, high series resistance and Schottky barrier height caused degradation in output characteristic of n-MOSFET. Subsequently, an alternative high-κ material, ZrO2, was carried out to study the gate stack without any intentional interfacial layer on the Ge substrate. The ZrO2 thin film was deposited by plasma-enhanced ALD with TEMAZr precursor. The effect of growth and PDA temperature on MOSCaps was electrically and physically analyzed. Even through the electrical analysis of MOSCaps, the EOT and Dit of ZrO2/Ge gate stack with PDA at 600 °C in N2 ambient were 1.33 nm and 5.4 × 1011~2 × 1012 cm-2eV-1 near midgap, respectively. By using quasi-static C-V curve and Berglund integral, the band bending efficiency could be estimated from the surface potential. XPS spectra also showed that an ultra-thin GeOx layer was formed during ALD deposition. The Ge p-MOSFETs and n-MOSFETs with ZrO2 gate stack were performed by both gate-last and gate-first processes to compare the pros and cons of two different schemes. The subthreshold swing using gate-last process was ~119.1 mV/dec for p-MOSFET and ~112.5 mV/dec for n-MOSFET, while using gate-first process was ~121.9 mV/dec for p-MOSFET and ~105.3 mV/dec for n-MOSFET. Using gate-last scheme revealed larger series resistance for both p- and n-MOSFET, indicating dopants out-diffusion was much severe due to more thermal budget. The high-field hole mobility showed that the surface roughness was rougher for gate-last MOSFET, and cross-sectional TEM images also confirmed this inference. According to our demonstration, we consider ZrO2 was a stable material on Ge and using gate-first scheme could effectively reduce series resistance and in turn increase device performance. In order to integrate Ge on Si platform, we investigated hetero-epitaxial Ge on blanket substrate accompanying with high temperature cyclic annealing. By using in-situ annealing process, the epitaxial Ge film with 3-cycle high temperature annealing demonstrated that the Hall mobility increased from 325 to 1332 cm2/V-s, and the values of the full width at half maximum decreased from 0.097 to 0.058 degree. The dislocation density of epitaxial Ge film was around 106 ~ 107 cm-2. The selective growth of germanium into nanoscale trenches on silicon substrates was also demonstrated. The nanoscale trenches were fabricated using the state-of-the-art shallow trench isolation technique, and the smallest width was only 50 nm. Threading dislocations in Ge film could glide and be annihilated by high temperature annealing. In small trenches, threading dislocations could be readily removed because their gliding distance to the SiO2 sidewalls was short. In contrast, threading dislocations might combine and form sessile threading dislocations in larger pattern size. Nano-beam diffraction analysis showed that the epitaxial Ge film within the trenches was fully relaxed after cyclic thermal annealing. Finally, based on the previous experiences of fabricating gate stacks and hetero-epitaxy, integrating Ge thin film on silicon-on-insulator substrate and performing Ge fin field-effect-transistors (FinFETs) have been demonstrated. Directly grown Ge film on high resistivity thin SOI substrate provided a good platform for fabricating advanced Ge devices. The SOI structure could effectively suppress junction leakage; therefore, high Ion/Ioff ratio (~5 × 105, at VD = 0.1 V) of drain current has been achieved. Tri-gate structure provided better short channel control abilities for the Ge FinFETs, and the drain-induced-barrier-lowering (DIBL) and threshold voltage (VTH) shift could be maintained at the level of ~110 mV/V and ~0.1 V, respectively, for Ge n-channel FinFET with Lchannel = 120 nm and WFin = 40 nm. Multi-fin Ge FinFET with Lchannel = 170 nm and WFin = 50 nm was also illustrated. Both N- and P-FinFETs possess high Ion/Ioff ratio over 104. Besides, the sub-threshold swing could be reduced about 25% after forming gas annealing.