Abstract
AbstractThe rapid permeation and degradation of silazane‐based coatings by water vapor limit their application in combustion environments. Hence, this work reports on the reaction of the oligosilazane Durazane 1800 with an appropriate Yb‐complex by a molecular approach and its application as protective thin coatings (1.2 µm) for AISI 304 in comparison with the benchmark Durazane 2250 in combustion‐like environments. Fourier transform infrared‐ and nuclear magnetic resonance‐spectroscopy elucidate the reaction mechanism and the chemical structure of the resulting Yb‐modified silazanes, whereas elemental and X‐ray diffractometry analyses confirm the formation of crystalline β‐Yb2Si2O7 and SiO2 after pyrolysis at 1000 °C in air. Energy dispersive spectroscopy and X‐ray photoelectron spectroscopy profile analyses show the enhanced diffusion of Fe, Cr, and Mn from the substrate into the Yb50 coating, which is responsible for a better adhesion (23.7 MPa), scratch tolerance (38 N), and a decreased coefficient of thermal expansion‐mismatch to the substrate, resisting 9 thermal cycles between 1000 and 20 °C. Despite the low Yb‐silicate content (6.8 wt%), only minor damage is caused to the Yb50 coating after wet oxidation in moist flowing air (1000 °C for 15 h), whereas the Durazane 2250 coating spalled‐off. This is a clear indication of the potential of the Yb2Si2O7‐containing coatings to protect metals and ceramics in extreme combustion environments.
Highlights
Yb50 coating after wet oxidation in moist flowing air (1000 °C for 15 h), approach to increase the oxidation and whereas the Durazane 2250 coating spalled-off
The chemical modification of silazanes with ytterbium (Yb) was successfully carried out in order to increase the stability of silazane-based ceramic coatings in very harsh hot gas corrosion environments like gas turbines and exhaust lines at temperatures above 1200 °C
The hot gas corrosion stable phase β-Yb2Si2O7 was generated by the reaction of NH groups of the oligosilazane Durazane 1800 with Yb(ApTMS)3, followed by pyrolysis of the resulting Yb-modified silazanes in air
Summary
(PDC) route enables the application of silicon-based precursors (e.g., silazanes, siloxanes, and carbosilanes) as coatings. Www.advancedsciencenews.com the effects related to oxidation of chromia forming alloys.[1,7,24,25] the rapid degradation of silazane-based coatings by hot gas corrosion at temperatures above 1200 °C due to the formation of volatile Si(OH) represents an upper limit for their application.[21,24,26,27]. Our goal was to increase the stability of silazanebased coatings against hot gas corrosion in combustion environments by modifying the oligosilazane Durazane 1800 with ytterbium in order to yield ytterbium silicates upon pyrolysis in air. The discussion of the results is limited to 1000 °C, the obtained Yb2Si2O7 phase should increase the stability of silazane-based ceramic coatings against hot gas corrosion, enabling their use at temperatures above 1200 °C
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