Wide bandgap III-nitrides, including (AI,Ga,In)-N, have seen enormous success in their development especially in the latest stages of the 20th century. Many substantial problems had to be overcome before these materials could constitute useful devices. High density of dislocations due to the lack of lattice-matched substrates and low doping efficiency were the most challenging problems that researchers in this area had to face. At the beginning, it was hard to believe that a material with a dislocation density in the order of 10⁸–10¹⁰ cm⁻² would become the building block of many viable devices. However, thanks to the hard work of researches in this field, today blue/violet light-emitting diodes and laser diodes based on (Al,In,Ga)-N have been successfully commercialized. Blue/green LEDs have already found their market in full-color LCD displays and traffic lights, while blue LDs are expected to shortly replace red lasers in the current CD/DVD read/write systems. The unique properties of III-nitrides lead to a range of applications from optoelectronic devices to high-power electronics. The wide bandgap of GaN makes this material suitable not only for light emitting source but also for high-temperature applications. GaN and its alloys have the potential to form high power electronics such as transistors or thyristors. UV solar-blind photodetectors based on AlGaN have been demonstrated by several groups [1]. These detectors have applications in early missile threat detection and interception, chemical and biological threat detection, UV flame monitoring, and UV environmental monitoring. Due to the polar nature of the Ga-N bond, GaN does not possess inversion symmetry. Thus, when GaN is subject to an alternating electric field, the induced polarization is not symmetric. This property of GaN can be used in non-linear optics applications such as second-harmonic generation [2]. The same lack of inversion symmetry results in a huge piezoelectric field. There are some other conceivable applications for III-nitrides such as surface acoustic wave generation [3], acousto-optic modulator [4], and devices that utilize negative electron affinity [5].