In this thesis, we used mechanical exfoliation to produce few-layers rhenium selenide (ReSe2) flakes on a silicon wafer covered by 300-nm thick silicon dioxide. Standard electron-beam lithography and thermal evaporation were used to pattern gold (Au) electrodes on ReSe2 flakes. The as-fabricated field effect transistor (FET) devices of ReSe2 were annealed in a high vacuum to improve the metal contact and to reduce the contact resistance. The devices were then electrically characterized. At room temperature, ReSe2 reveals itself as a n-type semiconductor, showing an on-off ratio of current up to 106. We studied electron transport in the ReSe2 FET devices in a wide temperature range from 80 K to 600 K. At a temperature below 200 K, electron transport in ReSe2 is well described by the theory of two-dimensional Mott’s variable range hopping. In this temperature range, we have discovered a phase transition from an insulator to a metallic state with increasing carrier concentration, adjusted by the back-gating voltage. As a temperature in the range between 300 K and 500 K, electron transport in ReSe2 is well described by thermally activated transport. When the temperature is higher than 500 K, the few-layers ReSe2 flakes changes from semiconducting to metallic behaviors once more. It reveals another insulator-to-metal transition at such a high temperature. This transition could originates from the electron-phonon interactions. ReSe2 is known for its anisotropic electrical property. Here we make multiple probes to measure electrical properties in different lattice orientations. We measured transfer characteristics of ReSe2 FET devices in several different orientations. As a first step, we set the orientation of 0° as the direction showing the highest mobility. We found that the direction of the lowest mobility is always exhibiting at 90°. In addition, we studied the anisotropy of electron transport at temperatures from 80 to 300 K. We learned that the anisotropy effect in ReSe2 only gives a different magnitude of conductance in different orientation while the mechanism of electron transport is the same in all directions.