Memristors, also known as memory resistors, have gained widespread attention for their applications in simulating biological synapses due to their structural similarity to synapses and their superior capabilities in information storage and processing. In the case of MoS₂ memristors, hysteresis is associated with the switching behavior among various resistance states. The presence of hysteresis renders MoS₂ as a potential candidate for memristor and could be used for neuromorphic applications in which gate and drain terminal acts as a pre and postsynaptic terminal and MoS₂ as a resistive channel.
In this study, we explored the impact of inorganic molecular insertion with AuCl₃ on the MoS₂ MOSFET to modulate its hysteresis behavior for memristive application. MoS₂ flakes were mechanically exfoliated onto a SiO₂ layer grown on a heavily doped p-type silicon substrate. Two-terminal electrodes were fabricated using photolithography patterning, and subsequently, inorganic molecular doping with AuCl₃ was carried out through drop-casting and annealing on the source/drain regions. Metal electrodes are then formed by the deposition of Au followed by lift off process. The introduction of AuCl₃ through inorganic molecular insertion increased trapping levels at the interface, attributed to Au-S bonding, leading to a significant hysteresis effect. The findings demonstrate the potential for modulating the hysteresis behavior in MoS₂ device through AuCl₃ doping. Nevertheless, additional optimization in doping techniques is essential to achieve a wider hysteresis effect suitable for neuromorphic applications.