AND Gate Response in a Double Mesoscopic Ring

Abstract: This study paved the way for the production of an electronic logic gate.

“…Double [23], triple [24] or more quantum dots are setting as complex systems [14] offers many quantum states that obvious themselves, e.g., in current rectification [25] and Pauli spin blockade [26]. The normal limit for reducing charge carrier intensity is individual charge nano electronics, where externals such as conductance and current may be adjusted with single charge accuracy [27][28][29]. The transmission probability of an electron passes through the ADQD structure can be controlled efficiently by changing the direction of the current or the polarity of voltage [25].…”

Asymmetric Double Quantum Dot Structure as Nanoscale Diode

“…Double [23], triple [24] or more quantum dots are setting as complex systems [14] offers many quantum states that obvious themselves, e.g., in current rectification [25] and Pauli spin blockade [26]. The normal limit for reducing charge carrier intensity is individual charge nano electronics, where externals such as conductance and current may be adjusted with single charge accuracy [27][28][29]. The transmission probability of an electron passes through the ADQD structure can be controlled efficiently by changing the direction of the current or the polarity of voltage [25].…”

Asymmetric Double Quantum Dot Structure as Nanoscale Diode

Possibility designing half-wave and full-wave molecular rectifiers by using single benzene molecule

The electronic properties of concentric double quantum ring and possibility designing XOR gate