In this work, we investigate the dynamics of a single electron surface trap, embedded in a self-assembly metallic double-dot system. The charging and discharging of the trap by a single electron is manifested as a random telegraph signal of the current through the double-dot device. We find that we can control the duration time that an electron resides in the trap through the current that flows in the device, between fractions of a second to more than an hour. We suggest that the observed switching is the electrical manifestation of the optical blinking phenomenon, commonly observed in semiconductor quantum dots.
We present an approach that allows forming a nanometric double dot single electron device. It uses chemical synthesis of metallic nanoparticles to form dimeric structures, e-beam lithography to define electrodes and gates, and electrostatic trapping to place the dimers in between the electrodes. We demonstrate a control of its charge configuration and conductance properties over a wide range of external voltages. This approach can be straightforwardly generalized to other material systems and may allow realizing quantum information devices.
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