Platinum diselenide PtSe2: An ambient-stable material for flexible electronics

[Display omitted] •TMDs such as PtSe2 are ideal candidates for flexible electronics, optoelectronics, and energy storage.•CuSe flux method for crystal growth and synchrotron-based XPS survey.•Mechanical properties such as modulus, hardness, and toughness analysed using nanoindentation.•Flexibility a...

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Published in:Materials science & engineering. B, Solid-state materials for advanced technology Solid-state materials for advanced technology, 2022-09, Vol.283, p.115824, Article 115824
Main Authors: Daws, Sawsan, Kotak, Parth, Kuo, Chia-Nung, Shan Lue, Chin, Politano, Antonio, Lamuta, Caterina
Format: Article
Language:English
Subjects:
Ambient stability
Electrical resistivity
Electronics
Energy storage
Flexible components
Flexible electronics
Fracture toughness
Mathematical analysis
Mechanical characterization
Mechanical properties
Modulus of elasticity
Nanoelectronics
Nanoindentation
Optoelectronics
Photoelectrons
Single crystals
Stability analysis
Strain hardening
Thickness
Transition metal compounds
Transition-metal dichalcogenides
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Summary:[Display omitted] •TMDs such as PtSe2 are ideal candidates for flexible electronics, optoelectronics, and energy storage.•CuSe flux method for crystal growth and synchrotron-based XPS survey.•Mechanical properties such as modulus, hardness, and toughness analysed using nanoindentation.•Flexibility and ambient stability of PtSe2 for long-term and electrical stability. Recent progress in the fabrication techniques and growth process of Transition-metal dichalcogenides (TMDs) such as PtSe2 has led to their application in a variety of fields ranging from flexible electronics to wearable optoelectronics, sensors, and energy storage. TMDs such as PtSe2 can be highly deformed without mechanical damage, have excellent electrical conductivity, and behave like a semiconductor when reduced to a single atomic layer thickness. Although considerable research has been devoted to theoretically understand the behavior of single layer PtSe2, there is a lack of information on the experimental characterization of the ambient stability and mechanical properties of bulk PtSe2. Therefore, in this study, the ambient stability and mechanical properties of single-crystal bulk PtSe2 are assessed using X-ray photoelectron spectroscopy and depth-sensing nanoindentation respectively. The average Young’s modulus and hardness values of PtSe2 are measured as 17.5 and 1.03 GPa respectively using nanoindentation testing. Furthermore, the experimentally calculated Young’s modulus is compared to DFT numerical simulations. The ductility of the material is highlighted using the strain hardening exponent (calculated value of 0.07) obtained from analyzing images of material pile-up at high indentation loads. The fracture toughness of PtSe2 is measured as 2.6MPam using nanoscratch experiments and the calculated value is found comparable to commonly used flexible electronics materials. Finally, ambient stability and flexibility tests underline the long-term and electrical stability of PtSe2 respectively. The characteristics of PtSe2 measured and showcased in this study will pave the way for deploying PtSe2 in various applications like nanoelectronics, opto-electronics, and photonics.
ISSN:0921-5107
1873-4944
DOI:10.1016/j.mseb.2022.115824