From Austenitic Stainless Steel to Expanded Austenite-S Phase: Formation, Characteristics and Properties of an Elusive Metastable Phase

Borgioli, Francesca

doi:10.3390/met10020187

Cited by 79 publications

(104 citation statements)

References 242 publications

(668 reference statements)

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“…The crystal structure of the S-phase also has a face-centered cubic structure, the S-phase was formed due to the incorporation of the nitrogen atoms in the interstitial positions and gaps of the austenite structure. Overall these findings are following results reported by many studies [55,56].…”

Section: Surface Microstructure Analysessupporting

confidence: 90%

“…It can be considered a nitrocarburizing treatment since the salts used often typically contribute carbon to the surface of the workpiece, and the two elements generally permeate into the surface of the industrial parts [48]. There have been researched studies of the effects of nitriding treatments on the behavior of surface microstructure and characteristics of austenitic stainless steel such as AISI 304 [49,50], AISI 304L [51], AISI 321 [52], AISI 201 [53], AISI 316 [54], AISI 316L [55,56], AISI 202 [57], AISI 316LN [58] and AISI 316LVM [59], AISI 310[60], AISI 303 [61], AISI 204 [62]. However, there is a lack of research about the surface microstructural and tribological behavior of AISI 316L stainless steel during salt bath nitriding by the Tenifer process (TF1) at 580 °C.…”

Section: Introductionmentioning

confidence: 99%

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Microstructure, Mechanical and Tribological Behaviour of Aisi 316l Stainless Steel During Salt Bath Nitriding

Ghelloudj

2021

Acta Metall Slovaca

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The aim of the current work was to analyse the impact of salt bath nitriding on the behavior of the tribological characteristics and surface microstructures of AISI 316L stainless steels. Nitriding was carried out at 580°C for 10 h. The tribological, structural behavior of the AISI 316L before and after salt bath nitriding was compared. The surface microstructures, tribological characteristics, as well as its surface hardness, were investigated using optical microscopy (OM), X-ray diffractometer (XRD), surface profilometer, pin-on-disk wear tester and microhardness tester. In the current work the experimental results showed that a great surface hardness could be achievable through salt bath nitriding technique because of the formation of the so-called expanded Austenite (S-phase), the nitrogen diffusion region. The surface hardness of AISI 316 stainless steel after nitriding process reached 1100 HV0.025 which was six times the untreated sample hardness. The S-phase is additionally expected to the improvement of wear resistance and decrease the friction coefficient.

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Section: Surface Microstructure Analysessupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Microstructure, Mechanical and Tribological Behaviour of Aisi 316l Stainless Steel During Salt Bath Nitriding

Ghelloudj

2021

Acta Metall Slovaca

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“…Figure 5 shows the untreated EDS, T500W3, T550W7, and T600W7 specimens. The most strategic areas to be observed were those closer to the surface, which had the highest number of N atoms detected 24) . Furthermore, no N atoms were detected on untreated specimens.…”

Section: Eds Observationmentioning

confidence: 99%

Surface Modification and Hardness Behavior of AISI 304 as an Artificial Hip Joint using Ammonia and Scallop Shell Powder as a Nitriding Agent

Triyono¹,

Rahajeng²,

Surojo³

2021

Evergreen

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Surface modification was carried out in AISI 304 using ammonia and scallop shell powder as the nitriding agent. Furthermore, the temperature variations used were 500°, 550° and 600°C within the durations of 3, 5, and 7 hours. The results showed that the highest point of specimen hardness reached 600°C at 7 hours (1246 VHN) with a nitrogen content of 15.35% and a nitride layer depth of 141.64 µm. In addition, this value was higher than other implant materials, namely AISI 316L (316 VHN), Ti6Al4V (435 VHN), CrCoMo (351 VHN) and human bone (129 VHN).

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“…Low-temperature plasma nitriding and carburizing at temperatures less than 450 • C for austenitic stainless steels can improve their wear resistance. Rather than producing a nitride or carbide, this treatment produces supersaturated solid solution of nitrogen or carbon in the face-centered cubic lattice, which is known as the S-phase (or the expanded austenite) [27][28][29][30][31][32][33]. Accordingly, the corrosion resistance does not degrade because the ability to form a passive film is maintained after plasma treatment [34,35].…”

Section: Introductionmentioning

confidence: 99%

Formation and Properties of Nitrocarburizing S-Phase on AISI 316L Stainless Steel-Based WC Composite Layers by Low-Temperature Plasma Nitriding

Adachi

Yamaguchi

Ueda

2021

Metals

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Stainless steel-based WC composite layers fabricated by a laser cladding technique, have strong mechanical strength. However, the wear resistance of WC composite layers is not sufficient for use in severe friction and wear environments, and the corrosion resistance is significantly reduced by the formation of secondary carbides. Low-temperature plasma nitriding and carburizing of austenitic stainless steels, treated at temperatures of less than 450 °C, can produce a supersaturated solid solution of nitrogen or carbon, known as the S-phase. The combined treatment of nitriding and carburizing can form a nitrocarburizing S-phase, which is characterized by a thick layer and superior cross-sectional hardness distribution. During the laser cladding process, free carbon was produced by the decomposition of WC particles. To achieve excellent wear and corrosion resistance, we attempted to use this free carbon to form a nitrocarburizing S-phase on AISI 316 L stainless steel-based WC composite layers by plasma nitriding alone. As a result, the thick nitrocarburizing S-phase was formed. The Vickers hardness of the S-phase ranged from 1200 to 1400 HV, and the hardness depth distribution became smoother. The corrosion resistance was also improved through increasing the pitting resistance equivalent numbers due to the nitrogen that dissolved in the AISI 316 L steel matrix.

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From Austenitic Stainless Steel to Expanded Austenite-S Phase: Formation, Characteristics and Properties of an Elusive Metastable Phase

Cited by 79 publications

References 242 publications

Microstructure, Mechanical and Tribological Behaviour of Aisi 316l Stainless Steel During Salt Bath Nitriding

Microstructure, Mechanical and Tribological Behaviour of Aisi 316l Stainless Steel During Salt Bath Nitriding

Surface Modification and Hardness Behavior of AISI 304 as an Artificial Hip Joint using Ammonia and Scallop Shell Powder as a Nitriding Agent

Formation and Properties of Nitrocarburizing S-Phase on AISI 316L Stainless Steel-Based WC Composite Layers by Low-Temperature Plasma Nitriding

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