High Current Density Electrical Breakdown of TiS3 Nanoribbon-Based Field-Effect Transistors

Aday J. Molina-Mendoza; Joshua O. Island; Wendel S. Paz; Jose Manuel Clamagirand; Jose Ramón Ares; Eduardo Flores; Fabrice Leardini; Carlos Sánchez; Nicolás Agraït; Gabino Rubio-Bollinger; Herre S.J. van der Zant; Isabel J. Ferrer; JJ Palacios; Andres Castellanos-Gomez

doi:10.1002/adfm.201605647

High Current Density Electrical Breakdown of TiS₃ Nanoribbon-Based Field-Effect Transistors

Aday J. Molina-Mendoza^*, Joshua O. Island, Wendel S. Paz, Jose Manuel Clamagirand, Jose Ramón Ares, Eduardo Flores, Fabrice Leardini, Carlos Sánchez, Nicolás Agraït, Gabino Rubio-Bollinger, Herre S.J. van der Zant, Isabel J. Ferrer, JJ Palacios, Andres Castellanos-Gomez

^*Corresponding author for this work

QN/van der Zant Lab

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

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Abstract

The high field transport characteristics of nanostructured transistors based on layered materials are not only important from a device physics perspective but also for possible applications in next generation electronics. With the growing promise of layered materials as replacements to conventional silicon technology, the high current density properties of the layered material titanium trisulfide (TiS₃) are studied here. The high breakdown current densities of up to 1.7 × 10⁶ A cm⁻² are observed in TiS₃ nanoribbon-based field-effect transistors, which are among the highest found in semiconducting nanomaterials. Investigating the mechanisms responsible for current breakdown, a thermogravimetric analysis of bulk TiS₃ is performed and the results with density functional theory and kinetic Monte Carlo calculations are compared. In conclusion, the oxidation of TiS₃ and subsequent desorption of sulfur atoms play an important role in the electrical breakdown of the material in ambient conditions. The results show that TiS₃ is an attractive material for high power applications and lend insight into the thermal and defect activated mechanisms responsible for electrical breakdown in nanostructured devices.

Original language	English
Article number	1605647
Number of pages	9
Journal	Advanced Functional Materials
Volume	27
Issue number	13
DOIs	https://doi.org/10.1002/adfm.201605647
Publication status	Published - 5 Apr 2017

Bibliographical note

Accepted Author Manuscript

Keywords

2D materials
field-effect transistors
high current density
thermal stability
titanium trisulfide
transition metal trichalcogenides

Access to Document

10.1002/adfm.201605647

1704.05379Accepted author manuscript, 1.83 MB

Cite this

Molina-Mendoza, A. J., Island, J. O., Paz, W. S., Clamagirand, J. M., Ares, J. R., Flores, E., Leardini, F., Sánchez, C., Agraït, N., Rubio-Bollinger, G., van der Zant, H. S. J., Ferrer, I. J., Palacios, JJ., & Castellanos-Gomez, A. (2017). High Current Density Electrical Breakdown of TiS₃ Nanoribbon-Based Field-Effect Transistors. Advanced Functional Materials, 27(13), Article 1605647. https://doi.org/10.1002/adfm.201605647

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abstract = "The high field transport characteristics of nanostructured transistors based on layered materials are not only important from a device physics perspective but also for possible applications in next generation electronics. With the growing promise of layered materials as replacements to conventional silicon technology, the high current density properties of the layered material titanium trisulfide (TiS3) are studied here. The high breakdown current densities of up to 1.7 × 106 A cm−2 are observed in TiS3 nanoribbon-based field-effect transistors, which are among the highest found in semiconducting nanomaterials. Investigating the mechanisms responsible for current breakdown, a thermogravimetric analysis of bulk TiS3 is performed and the results with density functional theory and kinetic Monte Carlo calculations are compared. In conclusion, the oxidation of TiS3 and subsequent desorption of sulfur atoms play an important role in the electrical breakdown of the material in ambient conditions. The results show that TiS3 is an attractive material for high power applications and lend insight into the thermal and defect activated mechanisms responsible for electrical breakdown in nanostructured devices.",

keywords = "2D materials, field-effect transistors, high current density, thermal stability, titanium trisulfide, transition metal trichalcogenides",

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Molina-Mendoza, AJ, Island, JO, Paz, WS, Clamagirand, JM, Ares, JR, Flores, E, Leardini, F, Sánchez, C, Agraït, N, Rubio-Bollinger, G, van der Zant, HSJ, Ferrer, IJ, Palacios, JJ & Castellanos-Gomez, A 2017, 'High Current Density Electrical Breakdown of TiS₃ Nanoribbon-Based Field-Effect Transistors', Advanced Functional Materials, vol. 27, no. 13, 1605647. https://doi.org/10.1002/adfm.201605647

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AU - Molina-Mendoza, Aday J.

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AU - Paz, Wendel S.

AU - Clamagirand, Jose Manuel

AU - Ares, Jose Ramón

AU - Flores, Eduardo

AU - Leardini, Fabrice

AU - Sánchez, Carlos

AU - Agraït, Nicolás

AU - Rubio-Bollinger, Gabino

AU - van der Zant, Herre S.J.

AU - Ferrer, Isabel J.

AU - Palacios, JJ

AU - Castellanos-Gomez, Andres

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AB - The high field transport characteristics of nanostructured transistors based on layered materials are not only important from a device physics perspective but also for possible applications in next generation electronics. With the growing promise of layered materials as replacements to conventional silicon technology, the high current density properties of the layered material titanium trisulfide (TiS3) are studied here. The high breakdown current densities of up to 1.7 × 106 A cm−2 are observed in TiS3 nanoribbon-based field-effect transistors, which are among the highest found in semiconducting nanomaterials. Investigating the mechanisms responsible for current breakdown, a thermogravimetric analysis of bulk TiS3 is performed and the results with density functional theory and kinetic Monte Carlo calculations are compared. In conclusion, the oxidation of TiS3 and subsequent desorption of sulfur atoms play an important role in the electrical breakdown of the material in ambient conditions. The results show that TiS3 is an attractive material for high power applications and lend insight into the thermal and defect activated mechanisms responsible for electrical breakdown in nanostructured devices.

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