Nanoengineering liquid metal core–shell nanostructures
Nanoengineering liquid metal core–shell nanostructures
Nanoengineering the composition and morphology of functional nanoparticles endows them to perform multiple tasks and functions. An intriguing strategy for creating multifunctional nanomaterials involves the construction of core–shell nanostructures, which have enabled promising applications in biomedicine, energy, sensing, and catalysis. Here, a straightforward nanoengineering approach is presented utilizing liquid metal nanoparticles and galvanic replacement to create diverse core–shell nanostructures. Controlled nanostructures including liquid metal core-gold nanoparticle shell (LM@Au), gold nanoparticle core-gallium oxide shell (Au@Ga oxide), and hollow Ga oxide nanoparticles are successfully fabricated. Remarkably, these investigations reveal that LM@Au exhibits exceptional photothermal performance, achieving an impressive conversion efficiency of 65.9%, which is five times that of gold nanoparticles. By leveraging the high photothermal conversion efficiency and excellent biocompatibility of LM@Au, its promising application in hyperthermia cancer therapy is demonstrated. This simple yet powerful nanoengineering strategy opens new avenues for the controlled synthesis of complex core–shell nanostructures, advancing various fields beyond biomedicine.
core–shell nanostructures, galvanic replacement, liquid metals, photothermal conversion efficiency
Lu, Hongda
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Tang, Shi-Yang
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Zhu, Jiayuan
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Huang, Xumin
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Forgham, Helen
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Li, Xiangke
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Shen, Ao
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Yun, Guolin
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Hu, Jinming
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Zhang, Shiwu
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Davis, Thomas P.
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Li, Weihua
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Qiao, Ruirui
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Lu, Hongda
731b3c09-82ae-408b-8218-95b0de29f2dd
Tang, Shi-Yang
1d0f15c6-2a3e-4bad-a3d8-fc267db93ed4
Zhu, Jiayuan
9cb6abc4-66c8-480f-af88-7d324232c37e
Huang, Xumin
25e3f1a9-5c90-45c8-87cf-a2fd3552f646
Forgham, Helen
9f09d0be-87ea-4dd8-9345-f763b54245e5
Li, Xiangke
b28a0b2c-ae94-4a6c-9eb9-89c260a307a7
Shen, Ao
5ff5c7d4-2dc3-4d94-8b58-6802e0647b88
Yun, Guolin
240c3dc9-c224-41c0-8740-de165d1eb90b
Hu, Jinming
c2854a5d-c8e9-4a83-b7fa-a8ccd7596f58
Zhang, Shiwu
da008f91-71fa-42fb-879e-68b91429e1d6
Davis, Thomas P.
1041ec19-c740-4a43-bbaf-e8a740c2f658
Li, Weihua
e2555036-0e48-425a-afeb-db6ffba5238e
Qiao, Ruirui
cf0ce629-af33-47c2-81c5-6d62ccf80f7e
Lu, Hongda, Tang, Shi-Yang, Zhu, Jiayuan, Huang, Xumin, Forgham, Helen, Li, Xiangke, Shen, Ao, Yun, Guolin, Hu, Jinming, Zhang, Shiwu, Davis, Thomas P., Li, Weihua and Qiao, Ruirui
(2023)
Nanoengineering liquid metal core–shell nanostructures.
Advanced Functional Materials, [2311300].
(doi:10.1002/adfm.202311300).
Abstract
Nanoengineering the composition and morphology of functional nanoparticles endows them to perform multiple tasks and functions. An intriguing strategy for creating multifunctional nanomaterials involves the construction of core–shell nanostructures, which have enabled promising applications in biomedicine, energy, sensing, and catalysis. Here, a straightforward nanoengineering approach is presented utilizing liquid metal nanoparticles and galvanic replacement to create diverse core–shell nanostructures. Controlled nanostructures including liquid metal core-gold nanoparticle shell (LM@Au), gold nanoparticle core-gallium oxide shell (Au@Ga oxide), and hollow Ga oxide nanoparticles are successfully fabricated. Remarkably, these investigations reveal that LM@Au exhibits exceptional photothermal performance, achieving an impressive conversion efficiency of 65.9%, which is five times that of gold nanoparticles. By leveraging the high photothermal conversion efficiency and excellent biocompatibility of LM@Au, its promising application in hyperthermia cancer therapy is demonstrated. This simple yet powerful nanoengineering strategy opens new avenues for the controlled synthesis of complex core–shell nanostructures, advancing various fields beyond biomedicine.
Text
Adv Funct Materials - 2023 - Lu - Nanoengineering Liquid Metal Core Shell Nanostructures
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e-pub ahead of print date: 24 October 2023
Additional Information:
Funding Information:
R.Q. gratefully acknowledges the research funded by the National Health and Medical Research Council (APP1196850). This work used the Queensland node of the NCRIS‐enabled Australian National Fabrication Facility (ANFF) and the Centre for Microscopy and Microanalysis (CMM). S.‐Y.T. gratefully acknowledges the research funded by the Engineering and Physical Sciences Research Council (EPSRC) grant (EP/V008382/1). W.L. gratefully acknowledges the research funded by the Australian Research Council (DP230100823).
Keywords:
core–shell nanostructures, galvanic replacement, liquid metals, photothermal conversion efficiency
Identifiers
Local EPrints ID: 483509
URI: http://eprints.soton.ac.uk/id/eprint/483509
ISSN: 1616-301X
PURE UUID: 98b4116e-ba53-4d3d-9926-ecf97176fd10
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Date deposited: 01 Nov 2023 17:32
Last modified: 18 Mar 2024 04:13
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Contributors
Author:
Hongda Lu
Author:
Shi-Yang Tang
Author:
Jiayuan Zhu
Author:
Xumin Huang
Author:
Helen Forgham
Author:
Xiangke Li
Author:
Ao Shen
Author:
Guolin Yun
Author:
Jinming Hu
Author:
Shiwu Zhang
Author:
Thomas P. Davis
Author:
Weihua Li
Author:
Ruirui Qiao
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