This dissertation describes low-temperature transport measurements in two-dimensional electron gas systems. There are four research parts for different experiments. The first concerns the basic properties of two-dimensional electron gas systems, such as insulator, semiclassical oscillations and quantum Hall liquids at low magnetic fields. The second is a study of the renormalization group flow diagram through varying spin-splitting to delve into new quantum transport theories. The third discusses the non-monotonic magneto-resistivity due to Friedel’s oscillations. This is an important quantum transport property due to high electron concentration and strong electron-electron interactions. The fourth describes how electron heating can be a very powerful tool to study semiconductor devices. The quantum Hall effect is the most famous example in two-dimensional quantum transports. The concept of one-electron localization in the presence of a short-range disorder gives a good physics picture for understanding the phenomenon. All electron states in the broadened Landau level are localized except for electron with energy in the extended state. During the recent years, in the framework of a mean-field approximation, the concept of quasi-particles provides a more powerful tool for explaining more quantum transport properties. For example, the new boundary of global phase diagram due to low fields Landau level mixing may provide a way to explain direct insulator quantum Hall transition. The Separatrix of temperature driven flow lines may be caused by locally distribution of quasi-particles. The electron interaction causes non-monotonic magneto-resistivity due to Friedel’s oscillation by double back scattering of electrons. Electron heating may cause the non-uniform distribution of quasi-particles.