There has been growing interest in organic thin-film transistors (OTFTs) because of their potential applications in flexible, low-cost integrated circuits, such as smart cards, RF identification tags, and display backplanes, such as liquid crystal displays, electronic paper, and organic electroluminescent displays. [1,2] In particular, since organic semiconductors based on polymers and oligomers are attractive for their easy solution processing for film formation, recent research on OTFTs has been more focused on flexible electronic devices/display applications. Therefore, the most desired ultimate goal of organic semiconductor devices is to realize flexible electronics and displays that can be processed through all-solution processes including deposition of the active organic layers, the gate insulators, and the electrodes. Here we demonstrate all-solutionprocessed n-type organic transistors for the first time by depositing the source and drain metal by a spinning metal process.Despite the great interest and progress in organic and polymeric TFTs, most of the high field-effect-mobility OTFTs have been based on p-type channel materials. However, even if n-channel semiconducting materials are important for making ambipolar transistors [3,4] and complementary circuits, [5] they are relatively rare compared with the p-type materials. The reported field-effect mobilities of n-type OTFTs to date also show lower values than those of p-type devices. In addition, it has usually been observed that the solution-processed OTFTs show poorer performance than the vacuum-processed devices: for example, although the vacuum-evaporated pentacene transistor has shown high field-effect hole mobilities exceeding 1 cm 2 V ±1 s ±1 , [6] the solution-processed p-type transistor using the pentacene precursor showed low fieldeffect mobilities below 0.1 cm 2 V ±1 s ±1 . [7] Reports about the solution-processed n-type transistors are also relatively rare [5,8±10] and they usually show low charge-carrier mobilities (~10 ±2 cm 2 V ±1 s ±1 or less) [5,8,10,11] except that most recently the observation of a field-effect electron mobility as high as 0.1 cm 2 V ±1 s ±1 for a solution spin-coated conjugated ladder polymer was reported.[9] Here we report on solution-processed n-type OTFTs with high field-effect mobilities, based on the soluble derivatives of fullerene (C 60 ) as n-type channel materials. We obtained high field-effect electron mobilities of 0.02±0.1 cm 2 V ±1 s ±1 depending on the work-function of the source and drain metals, demonstrating that the electron injection current is contact-limited because of the Schottky barrier at the contact. Furthermore, we fabricated n-type OTFTs by an all-solution-deposition process including source and drain metals as well as gate insulators and organic semiconductors. These types of OTFTs are well suited for a wide range of existing and future flexible circuits and display applications that require a simplified production process and low-weight and low-cost products. In order to achieve the solu...
