Abstract
Traditional implementations of double-barrier quantum well structures (DBQWSs) have not been successful as oscillator sources at THz frequencies because they are utilized in an extrinsic (i.e., external charge exchange) manner. Indeed, the true failing of a “traditional” DBQWS-based oscillator is tied directly to the physical principles associated with its implementation. In this paper, greater insight into the physics of instabilities within nanoscale tunneling structures is revealed. Here, self-consistent, time-dependent Wigner–Poisson simulations demonstrate sustained THz-frequency current-oscillations in a DBQWS that arise without the benefit of external charging processes. More importantly, dependencies between the emitter-boundary structure and the DBQWS are identified that strongly influence the internal instability phenomenon. These new results offer potential methodologies for inducing and controlling intrinsic oscillations in DBQWSs.
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