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Current Density Equations Representing the Transition between the Injection- and Bulk-limited Currents for Organic Semiconductors  

Lee, Sang-Gun (Department of Information Science and Electrical Engineering, Kyushu University)
Hattori, Reiji (Art, Science, and Technology Center for Cooperative Research, Kyushu University)
Publication Information
Journal of Information Display / v.10, no.4, 2009 , pp. 143-148 More about this Journal
Abstract
The theoretical current density equations for organic semiconductors was derived according to the internal carrier emission equation based on the diffusion model at the Schottky barrier contact and the mobility equation based on the field dependence model, the so-called "Poole-Frenkel mobility model." The electric field becomes constant because of the absence of a space charge effect in the case of a higher injection barrier height and a lower sample thickness, but there is distribution in the electric field because of the space charge effect in the case of a lower injection barrier height and a higher sample thickness. The transition between the injection- and bulk-limited currents was presented according to the Schottky barrier height and the sample thickness change.
Keywords
organic semiconductor; theoretical equation; device simulation; injection-limited current; bulk-limited current; transition; ohmic contact;
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