Effect of external stress on γ nucleation and evolution in TiAl alloys

Teng, Chunyu; Du, An; Xu, Dongsheng; Wang, Y.; Yang, Rui

doi:10.1016/j.intermet.2015.05.003

Cited by 13 publications

(4 citation statements)

References 46 publications

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“…Extensive creep deformation studies have been carried out on a number of two phase near-c TiAI alloys produced by various processing routes [8,[19][20][21][22][23][24][25][26][27][28][29]. In addition, compression creep studies have been carried out on a number of binary single phase c-TiAl alloys and a number of literatures have reported that minimum strain rates during creep testing at different regimes of temperature and stress, is hugely dependent on the grain size of materials [1,8,19,30,31]. Minimum strain rate of such intermetallic alloys may be defined in terms of Mukherjee-Bird-Dorn equation [32][33][34].…”

Section: Introductionmentioning

confidence: 99%

A brief discussion on the tensile creep deformation behaviour of wrought single-phase γ-TiAl

Saha

2021

Materials Today: Proceedings

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Creep deformation behaviour in single phase c-TiAl alloy has been an extensively studied topic since the late 1970 s. A lot of literatures have reported creep behaviour of c-TiAl alloys, manufactured using different processing techniques [1][2][3][4][5][6][7]. The present discussion revisits the original work on understanding the tensile creep deformation behaviour of wrought single-phase c-TiAl alloy by Hayes et al. [8] and is aimed to develop an understanding of steady state creep, through strain vs strain rate and strain vs ln(strain rate) plots. Besides, it also attempts to study the variation of stress exponent with temperature between 760 and 900⁰C and also, to determine activation energies using the two most common approaches, namely: Zener-Hollomon (Z-H) [9] and Sherby-Dorn (S-D, temperature compensated time approach) [10] for stress levels of 69.4 and 103.4 MPa between 760 and 900⁰C.

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Section: Introductionmentioning

confidence: 99%

A brief discussion on the tensile creep deformation behaviour of wrought single-phase γ-TiAl

Saha

2021

Materials Today: Proceedings

View full text Add to dashboard Cite

show abstract

“…Extensive creep deformation studies have been carried out on a number of two phase near-γ TiAI alloys produced by various processing routes [8], [19]- [29]. In addition, compression creep studies have been carried out on a number of binary single phase γ-TiAl alloys and a number of literatures have reported that minimum strain rates during creep testing at different regimes of temperature and stress, is hugely dependent on the grain size of materials [1], [8], [19], [30], [31]. Minimum strain rate of such intermetallic alloys may be de ned in terms of Mukherjee-Bird-Dorn equation [32]- [34].…”

Section: Introductionmentioning

confidence: 99%

On the tensile creep deformation behaviour of wrought single-phase γ-TiAl

Saha

2021

Preprint

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Creep deformation behaviour in single phase γ-TiAl alloy has been an extensively studied topic since the late 1970s. A lot of literatures have reported creep behaviour of γ-TiAl alloys, manufactured using different processing techniques [1]–[7]. The present discussion revisits the original work on understanding the tensile creep deformation behaviour of wrought single-phase γ-TiAl alloy by Hayes et al. [8] and is aimed to develop an understanding of steady state creep, through strain vs strain rate and strain vs ln(strain rate) plots. Besides, it also attempts to study the variation of stress exponent with temperature between 760–900⁰C and also, to determine activation energies using the two most common approaches, namely: Zener-Hollomon (Z-H) [9] and Sherby-Dorn (S-D, temperature compensated time approach) [10] for stress levels of 69.4 and 103.4 MPa between 760–900⁰C.

show abstract

“…Extensive creep deformation studies have been c arried out on a number of two phase near-γ TiAI alloys produced by various processing routes [8], [19]- [29]. In addition, compression creep studies have been carried out on a number of binary single phase γ-TiAl alloys and a number of literatures have reported that minimum strain rates during creep testing at different regimes of temperature and stress, is hugely dependent on the grain size of materials [1], [8], [19], [30], [31]. Minimum strain rate of such intermetallic alloys may be defined in terms of Mukherjee-Bird-Dorn equation [32]- [34].…”

Section: Introductionmentioning

confidence: 99%

On the Tensile Creep Deformation Behaviour of Wrought Single-phase γ-TiAl

Saha¹

2021

Preprint

View full text Add to dashboard Cite

Creep deformation behaviour in single phase γ-TiAl alloy has been an extensively studied topic since the late 1970s. A lot of literatures have reported creep behaviour of γ-TiAl alloys, manufactured using different processing techniques [1]–[7]. The present discussion revisits the original work on understanding the tensile creep deformation behaviour of wrought single-phase γ-TiAl alloy by Hayes et al. [8] and is aimed to develop an understanding of steady state creep, through strain vs strain rate and strain vs ln(strain rate) plots. Besides, it also attempts to study the variation of stress exponent with temperature between 760-900⁰C and also, to determine activation energies using the two most common approaches, namely: Zener-Hollomon (Z-H) [9] and Sherby-Dorn (S-D, temperature compensated time approach) [10] for stress levels of 69 and 103.4 MPa between 760-900⁰C.

show abstract

Effect of external stress on γ nucleation and evolution in TiAl alloys

Cited by 13 publications

References 46 publications

A brief discussion on the tensile creep deformation behaviour of wrought single-phase γ-TiAl

A brief discussion on the tensile creep deformation behaviour of wrought single-phase γ-TiAl

On the tensile creep deformation behaviour of wrought single-phase γ-TiAl

On the Tensile Creep Deformation Behaviour of Wrought Single-phase γ-TiAl

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