Memory Effect and Negative Differential Resistance by Electrode‐ Induced Two‐Dimensional Single‐ Electron Tunneling in Molecular and Organic Electronic Devices

Abstract: Beyond the demonstration of single-molecule (or singleatom) and organic-thin-film transistors, [1±4] a reliable electrode contact remains one of the most critical challenges in the development of molecular and organic electronics. Except for the tip of a scanning tunneling microscope, [5±7] more practical connections often involve a metal/ insulator(semiconductor)/metal thin-film structure, either through a gate thin-film dielectric assembly below the source±drain, [1±4] or a insulating thin-film separator … Show more

“…[59,65] On the other hand, Tang et al argued that the SV model may not be a good one for the conductance switching, since it disregards potential energy changes resulting from the charging process. [64] They believe that the electrical behavior in their devices was caused by 2D single-electron tunneling by nanometer-sized metal islands, formed unexpectedly by the nucleation and growth of a metal thin-film electrode. Yet another model was proposed by Rozenberg et al [66] They proposed three kinds of metal domains in the film between the top and bottom electrodes: the top domain, the middle domain, and the bottom domain (Fig.…”

Electrical Switching and Bistability in Organic/Polymeric Thin Films and Memory Devices

“…[59,65] On the other hand, Tang et al argued that the SV model may not be a good one for the conductance switching, since it disregards potential energy changes resulting from the charging process. [64] They believe that the electrical behavior in their devices was caused by 2D single-electron tunneling by nanometer-sized metal islands, formed unexpectedly by the nucleation and growth of a metal thin-film electrode. Yet another model was proposed by Rozenberg et al [66] They proposed three kinds of metal domains in the film between the top and bottom electrodes: the top domain, the middle domain, and the bottom domain (Fig.…”

Electrical Switching and Bistability in Organic/Polymeric Thin Films and Memory Devices

“…From the damages shown on the failed devices, these spots were likely to be concentrated along the edges of the device. If the conduction paths were formed as a result of dust particles (Tang et al 2005), the on state current would be likely to be proportional to the device area. The off current showed a higher dependence on device area indicating a more uniform conduction mode.…”

Multi-layer stackable polymer memory devices

“…This charge-trapping mechanism was also adopted by various other groups [37,46]. Tang et al [47], however, argued that the SV model may not be a good one for conductance switching as it disregards potential energy changes resulting from the charging process. They believed that the electrical behavior in their devices was caused by 2D single-electron tunneling by nanometer-sized metal islands, formed unexpectedly by the nucleation and growth of a metal thin-film electrode.…”

Advancements in organic nonvolatile memory devices