Electrodeposition of amorphous Fe-Cr-Ni stainless steel alloy with high corrosion resistance, low cytotoxicity and soft magnetic properties

Bertero, Enrico; Hasegawa, Masaya; Staubli, Samuel; Pellicer, Eva; Herrmann, Inge K.; Sort, Jordi; Michler, Johann; Philippe, Laëtitia

doi:10.1016/j.surfcoat.2018.06.003

Cited by 31 publications

(17 citation statements)

References 36 publications

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“…1a). As reported in previous similar works, 26,30 the presence of cracks is mainly dependant on the thickness of the lm (crack-free samples obtained when coating thickness is less than 5 mm). However, crack-free coatings (thickness # 5 mm) started to crack immediately or a few days aer deposition, when the Cr content in the coating exceeded a certain amount (Cr $ 28 wt%).…”

Section: Anode Role Investigationsupporting

confidence: 76%

“…It could be expected that the higher amount of Ni (see Section 3.1.3) in the Ni anode samples would cause g-Fe to be the predominant phase in the electrodeposited lms (nickel retains austenitic phase in stainless steel 27 ). However, from one of our previous studies, 30 the microstructure of FeCrNi lms was found not to be inuenced by Cr and Ni concentrations. Therefore, the microstructure diversity is anode-dependant and most probably related to impurity variations.…”

Section: Anode Role Investigationmentioning

confidence: 64%

“…The FeCrNi electrodeposits present nodule-like features, which are undistinguishable in terms of composition with respect to the smooth surface, as observed in our previous work. 30 Nevertheless, the difference in anode material does not particularly affect the surface morphology of the studied coatings.…”

Section: Anode Role Investigationmentioning

confidence: 94%

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‘Green’ Cr(iii)–glycine electrolyte for the production of FeCrNi coatings: electrodeposition mechanisms and role of by-products in terms of coating composition and microstructure

et al. 2019

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Section: Anode Role Investigationsupporting

confidence: 76%

Section: Anode Role Investigationmentioning

confidence: 64%

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‘Green’ Cr(iii)–glycine electrolyte for the production of FeCrNi coatings: electrodeposition mechanisms and role of by-products in terms of coating composition and microstructure

et al. 2019

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“…As a result, more NaCl solution reaches the substrate material (copper) and an increased cathodic reaction takes place on the nobler copper, which shifts the corrosion current potential towards positive values. The difference in electrochemical behavior between the electrodeposited Fe-Cr-Ni samples and the AISI 304 stainless steel is attributed to the dissimilarities in the microstructure and chemical composition of the passive oxide film [26]. As previously shown in the study on the influence of heat treatment on the microstructure of Fe-Cr-Ni coatings, electrodeposited Fe-Cr-Ni alloys are amorphous or nanocrystalline in contrast to its metallurgical crystalline counterpart [11].…”

Section: Corrosion Resistance Of Coatingsmentioning

confidence: 70%

Electrodeposition of Thick and Crack-Free Fe-Cr-Ni Coatings from a Cr (III) Electrolyte

et al. 2022

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The electrodeposition of iron-nickel-chromium coatings is a more environmentally friendly and economical alternative to hard-chrome coatings made from chromium (VI) electrolytes and stainless-steel bulk materials. The aim of the study was to develop a suitable deposition method for thick and low-crack Fe-Cr-Ni coatings. Iron-nickel-chromium coatings were electrodeposited using a more ecological chromium (III) electrolyte with direct current (DC), stepped direct current, and pulse current (PC). The influence of the deposition method on the electrolyte aging, the alloy composition of the coating, and their microstructure was investigated. Corrosion studies of the Fe-Cr-Ni coatings in 3.5% NaCl solution were performed using polarization tests. Furthermore, hardness measurements and scratch tests were carried out to determine the adhesion strength. Phase analyses were performed by X-ray diffraction, and the chemical composition and microstructure were characterized by scanning electron microscopy. Using the stepped DC and PC method, crack-free Fe-Cr-Ni coatings were successfully deposited.

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“…[7][8][9]. However, recent researches find that there are some disadvantages in these implants: The toxic ions, Ni and Cr ions released from stainless steel, as well as Al released from titanium alloy, which will cause irreversible damage if absorbed excessively by the human body [10][11][12]; The elastic modulus of these bone implants is too much higher than that of natural bone, which can not avoid stress shielding effect [13,14]; These implants can not degrade completely by themselves, and they need to be taken out again after bone healing [15]. Therefore, it has become the focus of orthopedic clinic to find a suitable medical metal which releases no toxic ions, produce no stress shielding, and degrade at the same time.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Mg–xLi–Zn alloys for potential application of biodegradable bone implant materials

Zhou

Wang

et al. 2021

J Mater Sci: Mater Med

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Implant therapy after osteosarcoma surgery is a major clinical challenge currently, especially the requirements for mechanical properties, degradability of the implants, and their inhibition of residual tumor cells. Biodegradable magnesium (Mg) alloy as medical bone implant material has full advantages and huge potential development space. Wherein, Mg–lithium (Li) based alloy, as an ultra-light alloy, has good properties for implants under certain conditions, and both Mg and Li have inhibitory effects on tumor cells. Therefore, Mg–Li alloy is expected to be applied in bone implant materials for mechanical supporting and inhibiting tumor cells simultaneously. In this contribution, the Mg–xLi–Zinc (Zn) series alloys (x = 3 wt%, 6 wt%, 9 wt%) were prepared to study the influence of different elements and contents on the structure and properties of the alloy, and the biosafety of the alloy was also evaluated. Our data showed that the yield strength, tensile strength, and elongation of as-cast Mg–xLi–Zn alloy were higher than those of as-cast Mg–Zn alloy; Mg–xLi–Zn alloy can kill osteosarcoma cells (MG-63) in a concentration-dependent manner, wherein Mg–3Li–Zn alloy (x = 3 wt%) and Mg–6Li–Zn alloy (x = 6 wt%) promoted the proliferation of osteoblasts (MC3T3) at a certain concentration of Li. In summary, our study demonstrated that the Mg–6Li–Zn alloy could be potentially applied as a material of orthopedic implant for its excellent multi-functions.

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Electrodeposition of amorphous Fe-Cr-Ni stainless steel alloy with high corrosion resistance, low cytotoxicity and soft magnetic properties

Cited by 31 publications

References 36 publications

‘Green’ Cr(iii)–glycine electrolyte for the production of FeCrNi coatings: electrodeposition mechanisms and role of by-products in terms of coating composition and microstructure

‘Green’ Cr(iii)–glycine electrolyte for the production of FeCrNi coatings: electrodeposition mechanisms and role of by-products in terms of coating composition and microstructure

Electrodeposition of Thick and Crack-Free Fe-Cr-Ni Coatings from a Cr (III) Electrolyte

Investigation of Mg–xLi–Zn alloys for potential application of biodegradable bone implant materials

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