Abstract
Conducting and semiconducting organic materials have long been known [1], [2], but recent advances in chemical synthesis [3], [4] have enabled organic materials to begin delivering on the promise of mass-produced economical electronic devices. Organic electronic materials are better suited for constructing high-efficiency light-emitting diodes [5]–[8], solar cells [9], [10], and cheap solution-processable thin-film transistors [6], [11]–[18] than are crystalline inorganic semiconductors such as silicon and gallium arsenide. The electronic/optical properties and solubility of organic materials can be tuned independently by chemical synthesis [4]. Since they can be processed and patterned at ambient temperature, organic electronic materials are compatible with flexible large-area substrates [19].
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Silveira, W.R., Muller, E.M., Ng, T.N., Dunlap, D., Marohn, J.A. (2007). High-Sensitivity Electric Force Microscopy of Organic Electronic Materials and Devices. In: Kalinin, S., Gruverman, A. (eds) Scanning Probe Microscopy. Springer, New York, NY. https://doi.org/10.1007/978-0-387-28668-6_30
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