In SAW-driven single-photon source devices, the key component is a high-quality 2-D p-i-n junction. In addition, lateral 2-D p-n junctions are also potential candidates for investigating the properties of electron spins in low-dimensional systems by optical methods. In this thesis, we developed a reliable and relatively easy method to fabricate a lateral p–i–n junction in a completely undoped GaAs/AlGaAs quantum well structure by utilizing conventional metallization and lithography processes. An induced gas (2DEG or 2DHG) in undoped heterostructure shows great advantages compared to a doped gas, such as high mobility, especially in low carrier density. To gain the advantage of induced gas, we developed an induced lateral 2D p-i-n diode. The two different types of channels are induced via metal-insulator-semiconductor (MIS) gates, which called single-gate devices. With a negative voltage applied on the p-gates and a positive voltage applied on the n-gates, both 2DHG and 2DEG channels can be induced in the GaAs quantum well, so a lateral 2-D p-i-n diode is formed. The electrical and optical of the devices at low temperature are studied. The 2DEG and 2DHG can be induced at threshold voltage of 3.5 V and -1.25 V, respectively. The current-voltage curve of the devices shows clearly the rectifying behavior with a turn-on voltage of 1.53 V. This is in agreement with the theoretical calculation of the built-in voltage Vbi = 1.535 V. The main peak of electroluminescence is at 1.529 eV (811 nm) with the full-width at half-maximum of 4.4 meV. This is in good agreement with theoretical calculation of ground state energy of the quantum well. However, the gate control of the carriers in the quantum well is not very efficient because of the distant gate from the channel. As a result, the two top gates on the insulator could not be put too close to each other. This directly affects the carrier recombination in the i region. In addition, this limits further development more complicated devices, such as SAW-driven single-photon source. Thus, we developed the twin-gate structure which has surface gate and top gate for each channel. The surface Schottky gates provide a very good control for the carriers in the channel and at the same time can be put very close to each other. The top gates, which overlap the source and the drain through the insulator spacer, control the carriers in the channel regions next to the source and the drain without having a leakage path between the gates and the ohmic contacts. The twin-gate devices show more stable electrical characteristics and clearer optical spectrum. These results demonstrate that the device is promising for applications in the single-photon devices.