Galvanic exchange platinization reveals laser-inscribed pattern in 3D-LAM-printed steel

Galvanic exchange involving dissolution of iron and the simultaneous growth of platinum onto 316 L stainless steel was investigated for specimens manufactured by 3D-printing, and the behavior was compared to conventional stainless steel. Novel phenomena associated with the 3D-printed steel, but not...

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Published in	Journal of solid state electrochemistry Vol. 22; no. 6; pp. 1755 - 1762
Main Authors	Litherland, Alex G. M., Spurway, Lee M., Gordeev, Sergey N., Aaronson, Barak D. B., Wain, Andrew J., O’Connell, Michael A., Piili, Heidi, Hovilehto, Mikko, Matilainen, Ville-Pekka, Vuorema, Anne, Marken, Frank
Format	Journal Article
Language	English
Published	Berlin/Heidelberg Springer Berlin Heidelberg 01.06.2018 Springer Nature B.V
Subjects	Analytical Chemistry Austenitic stainless steels Bright plating Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Condensed Matter Physics Electrochemistry Energy Storage Original Paper Oxidation Physical Chemistry Platinum Porosity Stainless steel Steel industry Steel structures Three dimensional printing Laser pattern Catalysis Electroless deposition Alloys Nanoporosity
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Abstract	Galvanic exchange involving dissolution of iron and the simultaneous growth of platinum onto 316 L stainless steel was investigated for specimens manufactured by 3D-printing, and the behavior was compared to conventional stainless steel. Novel phenomena associated with the 3D-printed steel, but not conventional steel, reacting in three distinct phases were observed: first, with low platinum loading, a bright etching pattern linked to the laser-manufacturing process is revealed at the steel surface; second, a nanostructured pore pattern with platinum nano-deposits forms; and third, a darker platinum film coating of typically 500-nm thickness forms and then peels off the steel surface with further platinum growth underneath. Unlike the conventional steel (and mainly due to residual porosity), 3D-printed steel supports well-adhered platinum films for potential application in electrocatalysis, as demonstrated for alkaline methanol oxidation. Graphical abstract ᅟ
AbstractList	Galvanic exchange involving dissolution of iron and the simultaneous growth of platinum onto 316 L stainless steel was investigated for specimens manufactured by 3D-printing, and the behavior was compared to conventional stainless steel. Novel phenomena associated with the 3D-printed steel, but not conventional steel, reacting in three distinct phases were observed: first, with low platinum loading, a bright etching pattern linked to the laser-manufacturing process is revealed at the steel surface; second, a nanostructured pore pattern with platinum nano-deposits forms; and third, a darker platinum film coating of typically 500-nm thickness forms and then peels off the steel surface with further platinum growth underneath. Unlike the conventional steel (and mainly due to residual porosity), 3D-printed steel supports well-adhered platinum films for potential application in electrocatalysis, as demonstrated for alkaline methanol oxidation. Galvanic exchange involving dissolution of iron and the simultaneous growth of platinum onto 316 L stainless steel was investigated for specimens manufactured by 3D-printing, and the behavior was compared to conventional stainless steel. Novel phenomena associated with the 3D-printed steel, but not conventional steel, reacting in three distinct phases were observed: first, with low platinum loading, a bright etching pattern linked to the laser-manufacturing process is revealed at the steel surface; second, a nanostructured pore pattern with platinum nano-deposits forms; and third, a darker platinum film coating of typically 500-nm thickness forms and then peels off the steel surface with further platinum growth underneath. Unlike the conventional steel (and mainly due to residual porosity), 3D-printed steel supports well-adhered platinum films for potential application in electrocatalysis, as demonstrated for alkaline methanol oxidation. Graphical abstract ᅟ
Author	Litherland, Alex G. M. Spurway, Lee M. Matilainen, Ville-Pekka Marken, Frank Vuorema, Anne Gordeev, Sergey N. Hovilehto, Mikko Wain, Andrew J. O’Connell, Michael A. Piili, Heidi Aaronson, Barak D. B.
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Snippet	Galvanic exchange involving dissolution of iron and the simultaneous growth of platinum onto 316 L stainless steel was investigated for specimens manufactured... Galvanic exchange involving dissolution of iron and the simultaneous growth of platinum onto 316 L stainless steel was investigated for specimens manufactured...
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SubjectTerms	Analytical Chemistry Austenitic stainless steels Bright plating Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Condensed Matter Physics Electrochemistry Energy Storage Original Paper Oxidation Physical Chemistry Platinum Porosity Stainless steel Steel industry Steel structures Three dimensional printing
Title	Galvanic exchange platinization reveals laser-inscribed pattern in 3D-LAM-printed steel
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