rgtgx1549536955.txt

In order to break into further market segments, however, improvements in performance are still needed. Organic semiconductors enable the fabrication of large-scale printed and mechanically flexible electronic. applications, and have already successfully established themselves on the market Tester for displays in the form of organic light-emitting diodes (OLEDs). In semiconductor technology, doping refers to the targeted introduction of impurities (also called dopants) into the semiconductor material of an integrated circuit. Even the smallest amounts of these can have a very strong influence on electrical conductivity. Molecular doping is an integral part of the majority of commercial organic electronics applications. Until now, however, an insufficient fundamental physical understanding of the transport mechanisms of charges in doped organic semiconductors has prevented a further increase in conductivity to match the best inorganic semiconductors such as silicon.. These dopants function as intentional "disturbances" in the semiconductor that can be used to specifically control the behaviour of the charge carriers and thus the electrical conductivity of the original material. Doping is the answer