Deterministic grayscale nanotopography to engineer mobilities in strained MoS2 FETs

Xia Liu; Berke Erbas; Ana Conde-Rubio; Norma Rivano; Zhenyu Wang; Jin Jiang; Siiri Bienz; Naresh Kumar; Thibault Sohier; Marcos Penedo; Mitali Banerjee; Georg Fantner; Renato Zenobi; Nicola Marzari; Andras Kis; Giovanni Boero; Juergen Brugger

doi:10.1038/s41467-024-51165-4

Deterministic grayscale nanotopography to engineer mobilities in strained MoS₂ FETs

Xia Liu^*, Berke Erbas, Ana Conde-Rubio, Norma Rivano, Zhenyu Wang, Jin Jiang, Siiri Bienz, Naresh Kumar, Thibault Sohier, Marcos Penedo, Mitali Banerjee, Georg Fantner, Renato Zenobi, Nicola Marzari, Andras Kis, Giovanni Boero, Juergen Brugger^*

^*Corresponding author for this work

School of Integrated Circuits and Electronics

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

Field-effect transistors (FETs) based on two-dimensional materials (2DMs) with atomically thin channels have emerged as a promising platform for beyond-silicon electronics. However, low carrier mobility in 2DM transistors driven by phonon scattering remains a critical challenge. To address this issue, we propose the controlled introduction of localized tensile strain as an effective means to inhibit electron-phonon scattering in 2DM. Strain is achieved by conformally adhering the 2DM via van der Waals forces to a dielectric layer previously nanoengineered with a gray-tone topography. Our results show that monolayer MoS₂ FETs under tensile strain achieve an 8-fold increase in on-state current, reaching mobilities of 185 cm²/Vs at room temperature, in good agreement with theoretical calculations. The present work on nanotopographic grayscale surface engineering and the use of high-quality dielectric materials has the potential to find application in the nanofabrication of photonic and nanoelectronic devices.

Original language	English
Article number	6934
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-51165-4
Publication status	Published - Dec 2024

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Liu, X., Erbas, B., Conde-Rubio, A., Rivano, N., Wang, Z., Jiang, J., Bienz, S., Kumar, N., Sohier, T., Penedo, M., Banerjee, M., Fantner, G., Zenobi, R., Marzari, N., Kis, A., Boero, G., & Brugger, J. (2024). Deterministic grayscale nanotopography to engineer mobilities in strained MoS₂ FETs. Nature Communications, 15(1), Article 6934. https://doi.org/10.1038/s41467-024-51165-4

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title = "Deterministic grayscale nanotopography to engineer mobilities in strained MoS2 FETs",

abstract = "Field-effect transistors (FETs) based on two-dimensional materials (2DMs) with atomically thin channels have emerged as a promising platform for beyond-silicon electronics. However, low carrier mobility in 2DM transistors driven by phonon scattering remains a critical challenge. To address this issue, we propose the controlled introduction of localized tensile strain as an effective means to inhibit electron-phonon scattering in 2DM. Strain is achieved by conformally adhering the 2DM via van der Waals forces to a dielectric layer previously nanoengineered with a gray-tone topography. Our results show that monolayer MoS2 FETs under tensile strain achieve an 8-fold increase in on-state current, reaching mobilities of 185 cm²/Vs at room temperature, in good agreement with theoretical calculations. The present work on nanotopographic grayscale surface engineering and the use of high-quality dielectric materials has the potential to find application in the nanofabrication of photonic and nanoelectronic devices.",

author = "Xia Liu and Berke Erbas and Ana Conde-Rubio and Norma Rivano and Zhenyu Wang and Jin Jiang and Siiri Bienz and Naresh Kumar and Thibault Sohier and Marcos Penedo and Mitali Banerjee and Georg Fantner and Renato Zenobi and Nicola Marzari and Andras Kis and Giovanni Boero and Juergen Brugger",

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AU - Liu, Xia

AU - Erbas, Berke

AU - Conde-Rubio, Ana

AU - Rivano, Norma

AU - Wang, Zhenyu

AU - Jiang, Jin

AU - Bienz, Siiri

AU - Kumar, Naresh

AU - Sohier, Thibault

AU - Penedo, Marcos

AU - Banerjee, Mitali

AU - Fantner, Georg

AU - Zenobi, Renato

AU - Marzari, Nicola

AU - Kis, Andras

AU - Boero, Giovanni

AU - Brugger, Juergen

PY - 2024/12

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N2 - Field-effect transistors (FETs) based on two-dimensional materials (2DMs) with atomically thin channels have emerged as a promising platform for beyond-silicon electronics. However, low carrier mobility in 2DM transistors driven by phonon scattering remains a critical challenge. To address this issue, we propose the controlled introduction of localized tensile strain as an effective means to inhibit electron-phonon scattering in 2DM. Strain is achieved by conformally adhering the 2DM via van der Waals forces to a dielectric layer previously nanoengineered with a gray-tone topography. Our results show that monolayer MoS2 FETs under tensile strain achieve an 8-fold increase in on-state current, reaching mobilities of 185 cm²/Vs at room temperature, in good agreement with theoretical calculations. The present work on nanotopographic grayscale surface engineering and the use of high-quality dielectric materials has the potential to find application in the nanofabrication of photonic and nanoelectronic devices.

AB - Field-effect transistors (FETs) based on two-dimensional materials (2DMs) with atomically thin channels have emerged as a promising platform for beyond-silicon electronics. However, low carrier mobility in 2DM transistors driven by phonon scattering remains a critical challenge. To address this issue, we propose the controlled introduction of localized tensile strain as an effective means to inhibit electron-phonon scattering in 2DM. Strain is achieved by conformally adhering the 2DM via van der Waals forces to a dielectric layer previously nanoengineered with a gray-tone topography. Our results show that monolayer MoS2 FETs under tensile strain achieve an 8-fold increase in on-state current, reaching mobilities of 185 cm²/Vs at room temperature, in good agreement with theoretical calculations. The present work on nanotopographic grayscale surface engineering and the use of high-quality dielectric materials has the potential to find application in the nanofabrication of photonic and nanoelectronic devices.

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Deterministic grayscale nanotopography to engineer mobilities in strained MoS₂ FETs

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