Inkjet-Printed, High-Performance MoS 2 Transistors and Unipolar Logic Electronics

• Published in: ACS applied materials & interfaces Vol. 16; no. 32; pp. 42392 - 42405
• Main Authors: Mondal, Sandeep Kumar, Prakasan, Lakshmi, Kolluru, Naveen, Pradhan, Jyoti Ranjan, Dasgupta, Subho
• Format: Journal Article
• Language: English
• Published: United States 14.08.2024
• Subjects: printed electronics; MoS2; thin film transistors (TFTs); 2D semiconductors; unipolar logic electronics; inkjet printing; electrolyte gating
• ISSN: 1944-8244; 1944-8252
• DOI: 10.1021/acsami.4c05529

Two-dimensional (2D) semiconductor field-effect film transistors combine large carrier mobility with mechanical flexibility and therefore can be ideally suitable for wearable electronics or at the sensor interfaces of smart sensor systems. However, such applications require large-area solution processing as opposed to single-flake devices, where the critical challenge to overcome is the high interflake resistance values. In this report, using a narrow-channel, near-vertical transport device architecture, we have fabricated inkjet-printed sub-20 nm channel electrolyte-gated transistors with predominantly intraflake carrier transport. Therefore, the electronics transport in these transistors is not dominated by the high interflake resistance, and the intraflake material properties including doping density, defect concentration, contact resistance, and threshold voltage modulation can be examined and optimized independently to achieve a current density as high as 280 μA·μm . In addition, through the passivation of the sulfur vacancies with a tailored surface treatment, we demonstrate an impressive On-Off current ratio exceeding 1 × 10 , complemented by a low subthreshold swing of 100 mV·decade . Next, exploiting these high-performance transistors, unipolar depletion-load-type inverters have been fabricated that show a maximum gain of 31. Furthermore, we have realized NAND, NOR, and OR gates, demonstrating their seamless operation at a frequency of 1 kHz. Therefore, this work represents an important step forward to realize electronic circuits based on printed 2D thin film transistors.