Direct Laser Writing from Aqueous Precursors for Nano to Microscale Topographical Control, Integration, and Synthesis of Nanocrystalline Mixed Metal Oxides

Cody Kindle; Alexander Castonguay; Shannon McGee; John A. Tomko; Patrick E. Hopkins; Lauren D. Zarzar

doi:10.1021/acsanm.9b00360

Direct Laser Writing from Aqueous Precursors for Nano to Microscale Topographical Control, Integration, and Synthesis of Nanocrystalline Mixed Metal Oxides

Cody Kindle, Alexander Castonguay, Shannon McGee, John A. Tomko, Patrick E. Hopkins, Lauren D. Zarzar

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

22 Scopus citations

Abstract

As evidenced by the growth of additive manufacturing, there is extensive value in customization, both in terms of chemistry and structure. Direct laser writing is a promising approach to the maskless patterning of a broad range of nano to microscale materials. We employ a methodology using laser-induced solvothermal voxels, which combines the control of solvothermal chemistry for nanoparticle synthesis with the patterning abilities of direct laser writing, enabling the integration of nanocrystalline oxides, metals, and mixed metal oxides and alloys. We present an expanded range of materials that can be easily fabricated through this method and explore how this process can be used for 2.5D topographical patterning and layering with potential applications for catalysis and sensing.

Original language	English (US)
Pages (from-to)	2581-2586
Number of pages	6
Journal	ACS Applied Nano Materials
Volume	2
Issue number	5
DOIs	https://doi.org/10.1021/acsanm.9b00360
State	Published - May 24 2019

All Science Journal Classification (ASJC) codes

General Materials Science

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title = "Direct Laser Writing from Aqueous Precursors for Nano to Microscale Topographical Control, Integration, and Synthesis of Nanocrystalline Mixed Metal Oxides",

abstract = "As evidenced by the growth of additive manufacturing, there is extensive value in customization, both in terms of chemistry and structure. Direct laser writing is a promising approach to the maskless patterning of a broad range of nano to microscale materials. We employ a methodology using laser-induced solvothermal voxels, which combines the control of solvothermal chemistry for nanoparticle synthesis with the patterning abilities of direct laser writing, enabling the integration of nanocrystalline oxides, metals, and mixed metal oxides and alloys. We present an expanded range of materials that can be easily fabricated through this method and explore how this process can be used for 2.5D topographical patterning and layering with potential applications for catalysis and sensing.",

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AU - Kindle, Cody

AU - Castonguay, Alexander

AU - McGee, Shannon

AU - Tomko, John A.

AU - Hopkins, Patrick E.

AU - Zarzar, Lauren D.

PY - 2019/5/24

Y1 - 2019/5/24

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AB - As evidenced by the growth of additive manufacturing, there is extensive value in customization, both in terms of chemistry and structure. Direct laser writing is a promising approach to the maskless patterning of a broad range of nano to microscale materials. We employ a methodology using laser-induced solvothermal voxels, which combines the control of solvothermal chemistry for nanoparticle synthesis with the patterning abilities of direct laser writing, enabling the integration of nanocrystalline oxides, metals, and mixed metal oxides and alloys. We present an expanded range of materials that can be easily fabricated through this method and explore how this process can be used for 2.5D topographical patterning and layering with potential applications for catalysis and sensing.

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Direct Laser Writing from Aqueous Precursors for Nano to Microscale Topographical Control, Integration, and Synthesis of Nanocrystalline Mixed Metal Oxides

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