This thesis studied the preparation of various ultraviolet (UV)-curable polymeric composite resins (i.e. PU-acrylate/silica (weight ratio = 90 wt.%/10 wt.%), silicone-acrylate/Alumina (weight ratio = 90 wt.%/10 wt.%) as well as epoxy-acrylate/silica/Invar (weight ratio = 35 wt.%/50 wt.%/15 wt.%) and their applications for the packaging of organic light-emitting devices (OLEDs), organic solar cells (OSCs) and light-emitting diodes (LEDs). In the part of study relating to OLEDs, the lifetimes of devices were successfully enhanced by modulating the LiF thickness and utilizing the UV-curable silicone-acrylate adhesives for encapsulation. It was found that the LiF and lab-made encapsulating adhesives can effectively block the invasion of moisture as well as oxygen in the atmosphere into the OLEDs so that an 18-folds increment of lifetimes was achieved after encapsulation. A low turn-on voltage (3 V), high luminance (4850 cd/m2 at 9 V), color/luminance tunable OLED with device structure as ITO glass/naphthyl phenyl benzidine (NPB; 80 nm)/4,4’-bis(diphenylvinylenyl)- biphenyl (ADS082BE; 35 nm)/1,3-bis[2-(2,2’-bipyridine-6-yl)-1,3,4-oxadiazo-5-yl] benzene (Bpy-OXD; 20 nm)/tris-[8-hydroxy- quinoline]aluminum (Alq3; 50 nm)/lithium fluoride (LiF; 3 nm )/aluminum (Al; 80 nm) was successfully fabricated in this study. Its electroluminescent properties (e.g., hue, luminescent intensity, etc.) could be modulated by the manipulation for the layer thickness of NPB/ADS082BE/Bpy-OXD and the applied bias. In addition, the UV-curable silicone-acrylate encapsulating resin exhibited excellent gas barrier capability so that the half-lifetimes of OLEDs and LEDs reached 98 and 18300 hrs while those without encapsulation were only 9 and 2400 hrs. The UV-curable epoxy-acrylate nanocomposite resins with good thermal stability, moderate adhesion strength and excellent gas barrier capability were also prepared in this work. In order to improve the gas blocking properties, the Invar alloy was also blended into the resins so as to increase the gas resistance and decrease resin shrinkage after UV curing. Experimental results revealed that introduction of epoxy-acrylate nanocomposite resins could effectively block the penetration of moisture as well as oxygen in the air into the devices and consequently promoted the lifetimes of OSCs. Fabrication of polymeric reflector cups for LEDs by using polyphenylene sulfide/poly(ethylene terephthalate) (PPS/PET) and PPS/nylon 6,6/glass fiber alloys via injection molding process was also presented in this work. In order to enhance their mechanical properties, the compatibilizer, PE-g-GMA, was first developed by grafting the glycidyl methacrylate (GMA) into the low-density polyethylene (LDPE) with initiators by reactive extrusion procedure in a twin screw extruder. PPS/PET and PPS/nylon 6,6/glass fiber alloys with various amounts of PE-g-GMA (PPS/PET/PE-g-GMA (wt./wt./wt.)=100/50/12.5; PPS/Nylon 6,6/Glass Fiber Alloy/ PE-g-GMA(wt./wt./wt./wt.) =100/50/45/12.5) were then prepared and their physical properties as well as feasibilities for the high-brightness LEDs were also analyzed.