A Precise Quantitative Analysis of Precipitates in Ti-bearing Interstitial-free Steel

Ishiguro, Yasuhide; Murayama, Takashi; Chino, Atsushi; Sato, Kaoru; Shima, Yoshinobu; Kido, Akimasa; Morita, Masaya

doi:10.2355/tetsutohagane1955.83.8_479

Cited by 6 publications

(29 citation statements)

References 8 publications

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“…Our prediction that Cu can diffuse very fast is inductively deduced. Interestingly, there have been some reports in the field of irradiation-induced embrittlement in material for atomic reactors, [32][33][34][35][36] which mention that Cu diffusion is about two orders of magnitude faster than Fe self-diffusion and is interpreted through Self-Interstitial-Atom (SIA) mechanism, although these experiments are carried out by using Fe-1%Cu or Fe/Cu/Fe diffusion pairs heat-treated at over 1000 C. In our opinion, these phenomena have the same origin to our reports [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] and each Cu-related or Cu-S-related phenomenon is viewed from a different angle.…”

Section: )supporting

confidence: 55%

“…Our standpoint [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] and reviews of past studies have already been mentioned in details in the first report. 1) In addition, the sulfide precipitation in ferrite region in Ti-added steel has been already reviewed again in the second paper.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, it has to be made clear whether solute carbon really exists in as-hot-rolled IF steel to prove that sulfide precipitation occurs along our proposed theory. [1][2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] Please note that the terminology is very confusing in this scientific field. There have been some reports to mention the correlation between age-hardening and solute carbon in ''Tistabilized Ultra Low Carbon Bake-Hardenable steel (Ti-ULC-BH)'', 25,26) whose chemical compositions are designed to be lower sulfur (<20 ppm) and/or higher Mn (>1%) to obtain BH properties so that carbon is partially and/or weakly stabilized into TiC by inhibiting the precipitation of Ti 4 C 2 S 2 .…”

Section: Introductionmentioning

confidence: 99%

“…Also, the precipitation in Ti-IF steel has been traditionally interpreted to finish only in austenite region and not to occur in ferrite region, except for some limited papers. [10][11][12][13][14][15][16][17][18][19][20][21][22][23][24] In other words, carbon in Ti-IF steel has been regarded as completely stabilized as carbide. Therefore, it has to be made clear whether solute carbon really exists in as-hot-rolled IF steel to prove that sulfide precipitation occurs along our proposed theory.…”

Section: Introductionmentioning

confidence: 99%

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Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (3) —Decrease of Copper Sulfide by Long-Time-Annealing in Ferrite Region—

Ishiguro¹,

Murayama²,

Fujita³

et al. 2009

Mater. Trans.

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This report corresponds to the third paper in three consecutive papers to know the whole sulfide precipitation in Ti-added steel by adding a new knowledge that even a trace level of copper (0.01%Cu) acts as a sulfide-former. The authors show the strange phenomenon of copper sulfide in Ti-added steel in long-time-annealing in ferrite region. When annealed for short time (ex. 90 s), much of Cu-S is precipitated, but the amount of Cu-S is small at longer-time-annealing, while TiS reduces and Ti 4 C 2 S 2 increases monotonically. This phenomenon does not mean that Cu-S is initially formed and then dissolved away, but the Cu-S precipitation should be interpreted as causal evidence of ''(re-)solute sulfur and its reprecipitation'' along the same concept in the first and the second papers. Long-time-annealing means that our proposed reaction ''4TiS + 2[C] ! Ti 4 C 2 S 2 + 2[S]'' proceeds rightward and the re-solute sulfur is re-precipitated as Ti 4 C 2 S 2 (and MnS). Consequently, the amount of Cu-S is small. In contrast, short-time-annealing is not long enough to stabilize re-solute sulfur as Ti 4 C 2 S 2 (and MnS) and much of sulfur still remains solute. Therefore the amount of Cu-S is increased.Furthermore, the phenomena in three consecutive papers is organized into an integrated concept to understand the whole sulfide precipitation in Ti-added steel in both austenite and ferrite region.

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Section: )supporting

confidence: 55%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (3) —Decrease of Copper Sulfide by Long-Time-Annealing in Ferrite Region—

Ishiguro¹,

Murayama²,

Fujita³

et al. 2009

Mater. Trans.

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“…[10][11][12][13][14][15][16][17][18][19][20] However, as in non-Ti-added steel does, (3) a residual level of Cu in Ti-added steel has been also believed to be solute in steel and there are no papers to mention the phenomenon of Cu-S precipitation induced by a tramp element of Cu.…”

mentioning

confidence: 99%

Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (1) —Precipitation in Austenite Region—

Ishiguro¹,

Murayama²,

Fujita³

et al. 2009

Mater. Trans.

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The authors previously reported that even a trace level of copper (0.01% Cu) acts as a sulfide-former to form copper sulfide (Cu-S) in nonTi-added steel in which Mn has been thought to be the only sulfide-former so far. A new concept of copper-related sulfide precipitation is now extended to Ti-added steel. In addition, the total sulfide precipitation in Ti-added steel is reconfigured with the new knowledge of Cu-S. The new concept is shown in three consecutive papers. This first paper focuses on the sulfide precipitation in austenite-heat-treated Ti-added steel.Through TEM observation and quantitative chemical analysis, it is reported that the sulfide precipitation in austenite-heat-treated Ti-added steel reflects not only the precipitation in the austenite region but also the inevitable precipitation behavior during the cooling process from austenite to ferrite region, especially trace-level-Cu-induced Cu-S precipitation in ferrite region during rapid cooling. The mechanism of the inevitable sulfide precipitation during the cooling process is mainly based upon TiS-decomposition-induced morphological change and the reprecipitation of sulfur which remains solute over precipitatable limit during the heat-treatment in austenite region, and is precisely discussed in relation with Cu-S precipitation. Purpose of Our Studies and Reviews of Past ReportsThrough three consecutive papers, 1,2) the authors demonstrate the comprehensive concepts of sulfide precipitation in Ti-added steel in austenite and ferrite regions with the addition of a new concept of copper sulfide (Cu-S) precipitation induced by a small amount of 0.01%Cu, as well as the rarely-mentioned concept that Ti 4 C 2 S 2 and MnS are formed in ferrite region. The first paper focuses on sulfide precipitation in austenite region, including the phenomena in austenite-heat-treated Ti-added steel with the subsequent various cooling pattern.The following review provides explanations and comments on past studies of Cu-related precipitation, together with our purposes. These items are mentioned only in this paper, the first part of three consecutive papers. Therefore, the following description includes phenomena in both austenite and ferrite regions, because these phenomena are related to each other and cannot be completely separated. Table 1 shows the overviews of past studies on both Curelated precipitation in steel and sulfide precipitation in steel, together with the purpose of the three consecutive studies. Each item below is referred to as a ''parenthetic No.'' in Table 1. First of all, it has been believed as an established theory that (1) a small amount of Cu in non-Ti-added steel exists as solid solution, and many people have not paid any attentions to it. However, as our group has already pointed out, (2) such a trace level of Cu acts as a sulfide-former to form copper sulfide (Cu-S) in non-Ti-added steel whose sulfide-former is only Mn (more precisely, 0.01%Cu). [3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] The first purpose is (#1) to...

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Precipitation in vanadium bearing ultralow carbon strip steels

Ooi¹,

Fourlaris²,

Tanner³

et al. 2006

Materials Science and Technology

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Two novel Ultra Low Carbon steels were investigated, one based on combined vanadium and titanium additions and the second based on titanium only additions. Grain size and mechanical property measurements have been performed on continuous annealed samples previously subjected to 80% cold rolling reduction on both strip steel grades. The recrystallisation and grain coarsening characteristics of annealed ULC strips have been studied. The amount of precipitated species, under equilibrium conditions, at various annealing temperatures has also been calculated using MT-DATA thermodynamic modelling software. TEM characterisation coupled with EDX study of the precipitation sequences on continuous annealing strips was also performed. Precipitate studies of the novel ULC steels confirmed the major role of TiC precipitates in retarding the recrystallisation behaviour of ULC strip steels. The role of vanadium addition in ULC steel grades in reducing the recrystallisation temperature of ULC strip steels was also identified.

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A Precise Quantitative Analysis of Precipitates in Ti-bearing Interstitial-free Steel

Cited by 6 publications

References 8 publications

Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (3) —Decrease of Copper Sulfide by Long-Time-Annealing in Ferrite Region—

Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (3) —Decrease of Copper Sulfide by Long-Time-Annealing in Ferrite Region—

Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (1) —Precipitation in Austenite Region—

Precipitation in vanadium bearing ultralow carbon strip steels

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A Precise Quantitative Analysis of Precipitates in Ti-bearing Interstitial-free Steel

Cited by 6 publications

References 8 publications

Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (3) &mdash;Decrease of Copper Sulfide by Long-Time-Annealing in Ferrite Region&mdash;

Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (3) &mdash;Decrease of Copper Sulfide by Long-Time-Annealing in Ferrite Region&mdash;

Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (1) &mdash;Precipitation in Austenite Region&mdash;

Precipitation in vanadium bearing ultralow carbon strip steels

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Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (3) —Decrease of Copper Sulfide by Long-Time-Annealing in Ferrite Region—

Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (3) —Decrease of Copper Sulfide by Long-Time-Annealing in Ferrite Region—

Sulfide Precipitation in Titanium-Added Steel with Residual Level of Copper (1) —Precipitation in Austenite Region—