Molecular doping allows enhancement and precise control of electrical properties of organic
semiconductors, and is thus of central technological relevance for organic (opto‐) …

Molecular doping is a key process to increase the density of charge carriers in organic
semiconductors. Doping-induced charges in polymer semiconductors result in the formation …

State‐of‐the‐art p‐type doping of organic semiconductors is usually achieved by employing
strong π‐electron acceptors, a prominent example being …

Doping is of great importance to tailor the electrical properties of semiconductors. However,
the present doping methodologies for organic semiconductors (OSCs) are either inefficient …

This paper reports an n-type dopant, neutral benzyl viologen (BV 0), for organic
semiconductors and their application as active layers in organic field-effect transistors …

Molecular doping, under certain circumstances, can be used to improve the charge transport
in organic semiconductors through the introduction of excess charge carriers which can in …

Incorporating the molecular organic Lewis acid tris (pentafluorophenyl) borane [B (C6F5) 3]
into organic semiconductors has shown remarkable promise in recent years for controlling …

Conspectus Today's information society depends on our ability to controllably dope
inorganic semiconductors, such as silicon, thereby tuning their electrical properties to …

Molecular doping can increase the conductivity of organic semiconductors and plays an
increasingly important role in emerging and established plastic electronics applications. 4 …

One of the most effective ways to tune the electronic properties of conjugated polymers is to
dope them with small‐molecule oxidizing agents, creating holes on the polymer and …