Laser Annealing-Induced Phase Transformation Behaviors of High Entropy Metal Alloy, Oxide, and Nitride Nanoparticle Combinations

Yun Li; Yee Yan Tay; Pio J.S. Buenconsejo; William Manalastas; Wei Han Tu; Hong Kit Lim; Teddy Salim; Michael O. Thompson; Srinivasan Madhavi; Chor Yong Tay; Kwan W. Tan

doi:10.1002/adfm.202211279

Laser Annealing-Induced Phase Transformation Behaviors of High Entropy Metal Alloy, Oxide, and Nitride Nanoparticle Combinations

Yun Li
, Yee Yan Tay
, Pio J.S. Buenconsejo
, William Manalastas
, Wei Han Tu
, Hong Kit Lim
, Teddy Salim
, Michael O. Thompson
, Srinivasan Madhavi
, Chor Yong Tay
, Kwan W. Tan

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

29 Scopus citations

Abstract

High entropy materials made up of dissimilar elements have enormous potentials in various fields and applications such as catalysis, energy generation and bioengineering. Developments of facile rapid synthesis routes toward functional multicomponent nanoparticles (NPs) of metals and ceramics with control of single/mixed crystalline structure configurations as well as understanding their transformative behaviors to enable unexpected properties, however, has remained challenging. Here a transient laser heating strategy to generate high entropy metal alloy, oxide, and nitride nanoparticles (HE-A/O/N NPs) is described. Laser irradiation of the identical metal salt mixture under different millisecond heating times provides direct control of cooling rates and thereby results in HEA NPs with tunable single- and multiphasic solid solution characteristics, atomic compositions, nanoparticle morphologies, and physicochemical properties. Extending the elemental selection to nitride-forming precursors enables laser-induced carbothermal reduction and nitridation of high entropy tetragonal rutile oxide nanoparticlesNPs to the cubic rock salt nitride phase. The combination of laser heating with spatially resolved X-ray diffraction facilitates combinatorial studies of phase transitions and reaction pathways of multicomponent nanoparticles. These findings provide a general strategy to design nonequilibrium multicomponent metal alloys and ceramic materials amalgamations for fundamental studies and practical applications such as carbon nanotube growth, water splitting, and antimicrobial applications.

Original language	English
Article number	2211279
Journal	Advanced Functional Materials
Volume	33
Issue number	13
DOIs	https://doi.org/10.1002/adfm.202211279
State	Published - Mar 23 2023
Externally published	Yes

Funding

This work was supported by a Singapore Ministry of Education AcRF Tier 2 grant (MOE-T2EP50221-0017) and a startup grant from Nanyang Technological University, Singapore. S.M. and W.M.Jr. acknowledge financial support from the National Research Foundation of Singapore (NRF) Investigatorship Award (NRFI 2017-08) and the Agency for Science, Technology and Research (A*STAR) grant (A20H3g2140). This work made use of research facilities at the Facility for Analysis, Characterization, Testing and Simulation (FACTS), Nanyang Technological University, Singapore. The authors gratefully acknowledge Y. M. Lam, R. V. Ramanujan, A.C. Grimsdale, S. J. Tan, and Z. L. Gan for helpful discussion and kind experimental assistance. This work was supported by a Singapore Ministry of Education AcRF Tier 2 grant (MOE‐T2EP50221‐0017) and a startup grant from Nanyang Technological University, Singapore. S.M. and W.M.Jr. acknowledge financial support from the National Research Foundation of Singapore (NRF) Investigatorship Award (NRFI 2017‐08) and the Agency for Science, Technology and Research (A*STAR) grant (A20H3g2140). This work made use of research facilities at the Facility for Analysis, Characterization, Testing and Simulation (FACTS), Nanyang Technological University, Singapore. The authors gratefully acknowledge Y. M. Lam, R. V. Ramanujan, A.C. Grimsdale, S. J. Tan, and Z. L. Gan for helpful discussion and kind experimental assistance.

Keywords

X-ray mapping
high entropy materials
laser annealing
metal alloys
nitrides
oxides
phase transitions

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10.1002/adfm.202211279

Cite this

Li, Y., Tay, Y. Y., Buenconsejo, P. J. S., Manalastas, W., Tu, W. H., Lim, H. K., Salim, T., Thompson, M. O., Madhavi, S., Tay, C. Y., & Tan, K. W. (2023). Laser Annealing-Induced Phase Transformation Behaviors of High Entropy Metal Alloy, Oxide, and Nitride Nanoparticle Combinations. Advanced Functional Materials, 33(13), Article 2211279. https://doi.org/10.1002/adfm.202211279

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abstract = "High entropy materials made up of dissimilar elements have enormous potentials in various fields and applications such as catalysis, energy generation and bioengineering. Developments of facile rapid synthesis routes toward functional multicomponent nanoparticles (NPs) of metals and ceramics with control of single/mixed crystalline structure configurations as well as understanding their transformative behaviors to enable unexpected properties, however, has remained challenging. Here a transient laser heating strategy to generate high entropy metal alloy, oxide, and nitride nanoparticles (HE-A/O/N NPs) is described. Laser irradiation of the identical metal salt mixture under different millisecond heating times provides direct control of cooling rates and thereby results in HEA NPs with tunable single- and multiphasic solid solution characteristics, atomic compositions, nanoparticle morphologies, and physicochemical properties. Extending the elemental selection to nitride-forming precursors enables laser-induced carbothermal reduction and nitridation of high entropy tetragonal rutile oxide nanoparticlesNPs to the cubic rock salt nitride phase. The combination of laser heating with spatially resolved X-ray diffraction facilitates combinatorial studies of phase transitions and reaction pathways of multicomponent nanoparticles. These findings provide a general strategy to design nonequilibrium multicomponent metal alloys and ceramic materials amalgamations for fundamental studies and practical applications such as carbon nanotube growth, water splitting, and antimicrobial applications.",

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author = "Yun Li and Tay, \{Yee Yan\} and Buenconsejo, \{Pio J.S.\} and William Manalastas and Tu, \{Wei Han\} and Lim, \{Hong Kit\} and Teddy Salim and Thompson, \{Michael O.\} and Srinivasan Madhavi and Tay, \{Chor Yong\} and Tan, \{Kwan W.\}",

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AU - Tay, Yee Yan

AU - Buenconsejo, Pio J.S.

AU - Manalastas, William

AU - Tu, Wei Han

AU - Lim, Hong Kit

AU - Salim, Teddy

AU - Thompson, Michael O.

AU - Madhavi, Srinivasan

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N2 - High entropy materials made up of dissimilar elements have enormous potentials in various fields and applications such as catalysis, energy generation and bioengineering. Developments of facile rapid synthesis routes toward functional multicomponent nanoparticles (NPs) of metals and ceramics with control of single/mixed crystalline structure configurations as well as understanding their transformative behaviors to enable unexpected properties, however, has remained challenging. Here a transient laser heating strategy to generate high entropy metal alloy, oxide, and nitride nanoparticles (HE-A/O/N NPs) is described. Laser irradiation of the identical metal salt mixture under different millisecond heating times provides direct control of cooling rates and thereby results in HEA NPs with tunable single- and multiphasic solid solution characteristics, atomic compositions, nanoparticle morphologies, and physicochemical properties. Extending the elemental selection to nitride-forming precursors enables laser-induced carbothermal reduction and nitridation of high entropy tetragonal rutile oxide nanoparticlesNPs to the cubic rock salt nitride phase. The combination of laser heating with spatially resolved X-ray diffraction facilitates combinatorial studies of phase transitions and reaction pathways of multicomponent nanoparticles. These findings provide a general strategy to design nonequilibrium multicomponent metal alloys and ceramic materials amalgamations for fundamental studies and practical applications such as carbon nanotube growth, water splitting, and antimicrobial applications.

AB - High entropy materials made up of dissimilar elements have enormous potentials in various fields and applications such as catalysis, energy generation and bioengineering. Developments of facile rapid synthesis routes toward functional multicomponent nanoparticles (NPs) of metals and ceramics with control of single/mixed crystalline structure configurations as well as understanding their transformative behaviors to enable unexpected properties, however, has remained challenging. Here a transient laser heating strategy to generate high entropy metal alloy, oxide, and nitride nanoparticles (HE-A/O/N NPs) is described. Laser irradiation of the identical metal salt mixture under different millisecond heating times provides direct control of cooling rates and thereby results in HEA NPs with tunable single- and multiphasic solid solution characteristics, atomic compositions, nanoparticle morphologies, and physicochemical properties. Extending the elemental selection to nitride-forming precursors enables laser-induced carbothermal reduction and nitridation of high entropy tetragonal rutile oxide nanoparticlesNPs to the cubic rock salt nitride phase. The combination of laser heating with spatially resolved X-ray diffraction facilitates combinatorial studies of phase transitions and reaction pathways of multicomponent nanoparticles. These findings provide a general strategy to design nonequilibrium multicomponent metal alloys and ceramic materials amalgamations for fundamental studies and practical applications such as carbon nanotube growth, water splitting, and antimicrobial applications.

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KW - nitrides

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Laser Annealing-Induced Phase Transformation Behaviors of High Entropy Metal Alloy, Oxide, and Nitride Nanoparticle Combinations

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Keywords

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