Potential-pH diagrams considering complex oxide solution phases for understanding aqueous corrosion of multi-principal element alloys

Wang, K.; Han, Junsoo; Gerard, Angela Y.; Scully, John R.; Zhou, Bi Cheng

doi:10.1038/s41529-020-00141-6

Cited by 31 publications

(30 citation statements)

References 53 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The thickness h Ni(OH) 2(s) starts at ≈ 5 nm, demonstrating fast initial growth, but plateaus during further oxidation potential change. This and other past literature utilized model Pourbaix diagrams and interpreted this phase evolution using ∆ f G values, but could not fully capture the pHdependent and depth-dependent scale formation [4,5,28].…”

Section: A Bulk and Ph/v Dependent Ni Film Growthmentioning

confidence: 93%

Thermodynamic descriptors to predict oxide formation in aqueous solutions

Walters,

Wang,

Rondinelli

2022

Preprint

View full text Add to dashboard Cite

We formulate the maximum driving force (MDF) parameter as a descriptor to capture the thermodynamic stability of aqueous surface scale creation over a range of environmental conditions. We use formation free energies, ∆ f Gs, sourced from high-throughput density functional theory (DFT) calculations and experimental databases to compute the maximum driving force for a wide variety of materials, including simple oxides, intermetallics, and alloys of varying compositions. We show how to use the MDF to describe trends in aqueous corrosion of nickel thin films determined from experimental linear-sweep-voltometry data. We also show how to account for subsurface oxidation behavior using depth-dependent effective chemical potentials. We anticipate this approach will increase overall understanding of oxide formation on chemically complex multielement alloys, where competing oxide phases can form during transient aqueous corrosion.

show abstract

Section: A Bulk and Ph/v Dependent Ni Film Growthmentioning

confidence: 93%

Thermodynamic descriptors to predict oxide formation in aqueous solutions

Walters,

Wang,

Rondinelli

2022

Preprint

View full text Add to dashboard Cite

show abstract

“…Many spinels (i.e., AB 2 O 4 structure, where A and B are two of the elements in the MPEA) can also form, but the availability of cations in the proper stoichiometric ratios is often limited. 391 Therefore, spinels do not seem to provide an explanation for good passivity. Other possibilities exist such as the formation of complex oxide solute solutions with atoms occupying the structure of a particular host atom or an entirely new oxide lattice structure containing multiple elements.…”

Section: Corrosion and Design Of Multiple Principal Element Alloysmentioning

confidence: 99%

“…Other possibilities exist such as the formation of complex oxide solute solutions with atoms occupying the structure of a particular host atom or an entirely new oxide lattice structure containing multiple elements. 391 Lastly, there is the possibility of the formation of phase-separated stoichiometric oxides, perhaps in layers or islands. Phase separation is more likely when approaching equilibrium conditions and when the oxides formed are insoluble.…”

Section: Corrosion and Design Of Multiple Principal Element Alloysmentioning

confidence: 99%

“…This cooperative effect can render an MPEA passive over a broad range of conditions, which is an improvement over a binary or ternary alloy with one or two oxides that are stable over a limited range in E and pH. Many spinels (i.e., AB 2 O 4 structure, where A and B are two of the elements in the MPEA) can also form, but the availability of cations in the proper stoichiometric ratios is often limited . Therefore, spinels do not seem to provide an explanation for good passivity.…”

Section: Metal Corrosionmentioning

confidence: 99%

“…Therefore, spinels do not seem to provide an explanation for good passivity. Other possibilities exist such as the formation of complex oxide solute solutions with atoms occupying the structure of a particular host atom or an entirely new oxide lattice structure containing multiple elements . Lastly, there is the possibility of the formation of phase-separated stoichiometric oxides, perhaps in layers or islands.…”

Section: Metal Corrosionmentioning

confidence: 99%

See 2 more Smart Citations

Recent Advances in Corrosion Science Applicable To Disposal of High-Level Nuclear Waste

et al. 2021

Self Cite

View full text Add to dashboard Cite

High-level radioactive waste is accumulating at temporary storage locations around the world and will eventually be placed in deep geological repositories. The waste forms and containers will be constructed from glass, crystalline ceramic, and metallic materials, which will eventually come into contact with water, considering that the period of performance required to allow sufficient decay of dangerous radionuclides is on the order of 105–106 years. Corrosion of the containers and waste forms in the aqueous repository environment is therefore a concern. This Review describes the recent advances of the field of materials corrosion that are relevant to fundamental materials science issues associated with the long-term performance assessment and the design of materials with improved performance, where performance is defined as resistance to aqueous corrosion. Glass, crystalline ceramics, and metals are discussed separately, and the near-field interactions of these different material classes are also briefly addressed. Finally, recommendations for future directions of study are provided.

show abstract

Recent insights in corrosion science from atomic spectroelectrochemistry

Choudhary

Ogle

Gharbi

et al. 2021

Electrochemical Science Adv

View full text Add to dashboard Cite

A fundamental understanding of corrosion mechanisms is the key to developing suitable corrosion protection approaches, and for the prediction of service life of metallic structures. However, conventional corrosion testing methods such as mass loss and electrochemical testing do not guarantee estimation of "true" corrosion rate and often mask the underlying mechanisms, due to either low sensitivity or a lack of element-resolved information. Relatively recent work in corrosion science has led to the development of a new class of corrosion testing approaches, namely atomic spectroelectrochemistry; whereby direct insight of dissolution and corrosion mechanisms can be obtained during electrochemical testing. Atomic spectroelectrochemistry provides real-time and element resolved dissolution rate of material via coupling electrochemical flow cell with inductively coupled plasma -atomic spectroscopy. This concise review discusses the basic working principle of atomic spectroelectrochemistry and its recent applications in corrosion science to understand the true underlying corrosion mechanisms of a range of metallic materials.

show abstract

Potential-pH diagrams considering complex oxide solution phases for understanding aqueous corrosion of multi-principal element alloys

Cited by 31 publications

References 53 publications

Thermodynamic descriptors to predict oxide formation in aqueous solutions

Thermodynamic descriptors to predict oxide formation in aqueous solutions

Recent Advances in Corrosion Science Applicable To Disposal of High-Level Nuclear Waste

Recent insights in corrosion science from atomic spectroelectrochemistry

Contact Info

Product

Resources

About