Germanium is a promising negative electrode candidate for lithium-ion thin-film batteries because of its very high theoretical storage capacity. When assuming full conversion of the material into the room-temperature equilibrium lithium saturated germanium phase , a theoretical capacity of or of germanium starting material is expected. However, the lithium-ion (de)insertion reaction of pure germanium thin films and the resulting electrochemical thermodynamic and kinetic properties are not yet fully understood. To address some of these questions, a combined electrochemical and in situ X-ray diffraction (XRD) study is presented. Results on the crystallographic phase transitions, occurring upon Li-(de)insertion of evaporated and sputtered germanium thin films are discussed. Moreover, the difference in reaction between evaporated and sputtered films is addressed. In addition, a detailed electrochemical investigation (cyclic voltammetry, galvanostatic intermittent titration technique, and electrochemical impedance spectroscopy) of evaporated germanium is conducted. The results reveal that evaporated and sputtered germanium crystallizes into when fully inserted with Li ions. This composition corresponds to a maximum storage capacity of or of germanium starting material.