technologies is described in manuscript. The charge transport properties of materials arecritical to optimize organic electronic devices. The importance of charge transport layersin the development of inverted bulk heterojunction polymer solar cells is the focus of andthe intrinsic bulk electron-phonon interaction and the behavior of mobility in the coherentregime of many systems, such as naphthalene, rubrene, and pentacene, is the focus of.Properties of materials that can be used organic semiconductors are reported inreferences. An overview of OFET-based biosensors, pressure sensors and e-nose/vapour sensors is presented in. The charge transport properties of dinaphtho2,3-b:2',3'-fthieno3,2-bthiophene single crystals in OFET is studied and its nonmonotonicpressure response is demonstrated. The review “Emerging Transparent ConductingElectrodes for Organic Light Emitting Diodes” focuses on the emerging alternativetransparent conducting electrodes materials for OLED applications, including carbonnanotubes, metallic nanowires, conductive polymers, and graphene .
Improvement in thelifetime of organic photovoltaic cells by using MoO3 in conjunction with tris-(8-hydroxyquinoline) aluminum as a cathode buffer layer is analysed. The concept ofbandgap science of organic semiconductor films for use in photovoltaic cells, chargecontrol by doping and design of the built-in potential based on precisely-evaluateddoping parameters is summarized in the manuscript. The use of electron and holetransport layers in the inverted bulk heterojunction polymer solar cells is the goal of thearticle. Bio-electronic devices can be used for developing OLEDs, OFETs and organicsolar cells and such components have many advantages especially the biodegradableproperty.3. FutureNew applications are likely to be in areas of biomedicine, lab-on-a-chip biomedicalapplication, optics, OFETs, OLEDs, displays, information technology, smartcards/RFIDtags, and sensors for environmental monitoring. The organic electronic devices will bevery promising in niche applications, especially due to the cheap manufacturing cost,flexibility, and ease to integrate with other systems.
OFETs prove to be important inapplications ranging from sophisticated medical diagnostics to “smart” clothes that candisplay changing images. OFET-based sensors have many advantages over other typesof sensors, such as signal amplification, high sensitivity, ease of fabrication, andminiaturization for multisensory arrays. Organic semiconductors can interact withdifferent chemicals and it is possible to convert the chemical information to electronicinformation, creating an “electronic nose”.
