Manipulation of the electrical and memory properties of MoS2 field-effect transistors by highly charged ion irradiation

Field-effect transistors based on molybdenum disulfide (MoS2) exhibit a hysteresis in their transfer characteristics, which can be utilized to realize 2D memory devices. This hysteresis has been attributed to charge trapping due to adsorbates, or defects either in the MoS2 lattice or in the underlying substrate. We fabricated MoS2 field-effect transistors on SiO2/Si substrates, irradiated these devices with Xe30+ ions at a kinetic energy of 180 keV to deliberately introduce defects and studied the resulting changes of their electrical and hysteretic properties. We find clear influences of the irradiation: while the charge carrier mobility decreases linearly with increasing ion fluence (up to only 20% of its initial value) the conductivity actually increases again after an initial drop of around two orders of magnitude. We also find a significantly reduced n-doping (approximate to 10(12) cm(-2)) and a well-developed hysteresis after the irradiation. The hysteresis height increases with increasing ion fluence and enables us to characterize the irradiated MoS2 field-effect transistor as a memory device with remarkably longer relaxation times (approximate to minutes) compared to previous works.

Automated summary

Field-effect transistors based on molybdenum disulfide (MoS2) were irradiated with Xe30+ ions to introduce defects and investigate their effects on electrical properties. The irradiation resulted in decreased charge carrier mobility and increased conductivity, as well as a significantly reduced n-doping and enhanced hysteresis. The irradiated MoS2 transistor exhibited memory-like behavior with remarkably longer relaxation times compared to previous works.