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Journal articles on the topic 'Dynamic strain aging'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 February 2022

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1

Ohmori, Masanobu, Yasunori Harada, Misao Itoh, and Fusahito Yoshida. "Dynamic Strain Aging in Chromium." Journal of the Japan Institute of Metals 54, no. 3 (1990): 270–75. http://dx.doi.org/10.2320/jinstmet1952.54.3_270.

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2

Mardoukhi, Ahmad, Jari Rämö, Taina Vuoristo, Amandine Roth, Mikko Hokka, and Veli-Tapani Kuokkala. "Effects of microstructure on the dynamic strain aging of ferriticpearlitic steels at high strain rates." EPJ Web of Conferences 183 (2018): 03009. http://dx.doi.org/10.1051/epjconf/201818303009.

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This paper presents an experimental study of the effects of dynamic strain aging on the mechanical behavior of selected high carbon and chromium-manganese steels in dynamic loading condition. In ferritic-pearlitic steels, the dynamic strain aging is typically caused by carbon, nitrogen, and possibly some other small solute atoms. Therefore, the thermomechanical treatments affect strongly how strong the dynamic strain aging effect is and at what temperature and strain rate regions the maximum effect is observed. In this work, we present results of the high temperature dynamic compression tests carried out for two different ferritic-pearlitic steels, 16MnCr5 and C60, that were heat treated to produce different microstructure variants of these standard alloys. The microstructures were analyzed using electron microscopy, and the materials were tested with the Split Hopkinson Pressure Bar device at three different strain rates at temperatures ranging from room temperature up to 680 °C to study the effect of the heat treatments and the resulting microstructures on the dynamic behavior of the steels and the dynamic strain aging effect. The results indicate that for both steels, a coarse grain structure has the strongest dynamic strain aging sensitivity at small plastic strains. However, at higher strains, all microstructures show similar strain aging sensitivities.
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3

Podrezov, Y. N., and L. G. Shtyka. "Dynamic strain aging of powdered iron." Powder Metallurgy and Metal Ceramics 36, no. 9-10 (September 1997): 491–95. http://dx.doi.org/10.1007/bf02680499.

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4

Mesarovic, Sinisa Dj. "Dynamic strain aging and plastic instabilities." Journal of the Mechanics and Physics of Solids 43, no. 5 (May 1995): 671–700. http://dx.doi.org/10.1016/0022-5096(95)00010-g.

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5

Wang, Xiaorong, and Christopher G. Robertson. "Memory of Prior Dynamic Strain History in Filled Rubbers." Rubber Chemistry and Technology 83, no. 2 (June 1, 2010): 149–59. http://dx.doi.org/10.5254/1.3548271.

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Abstract We recently discovered that particle-reinforced rubbers after being sheared (or aged) in oscillation at a frequency ƒa at a small strain γa (e.g., ∼1% strain) for time ta can often display a spectrum hole or drop in their dissipation spectra. The location of the hole depends on the aging strain amplitude γa. The depth of this hole is influenced by both the oscillatory aging frequency ƒa and the aging duration ta, and follows a simple power relationship of the product of ƒa and ta. Sequential shear at two strains reveals that when γa1>γa2 the resulting dynamic spectra appear to be a combination of that aged at γa1 and γa2, whereas for γa1>γa2, the resulting dynamic spectra only reflect the characteristic hole burning of the second strain after holding at γa2. This new memory effect occurs at very small strains in filled elastomers and involves material stiffening during the strain aging; both of those features are quite different from the Mullins effect. Also, this new memory is found to last for more than 10 days without any noticeable sign of disappearing.
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6

Fressengeas, C., A. J. Beaudoin, M. Lebyodkin, L. P. Kubin, and Y. Estrin. "Dynamic strain aging: A coupled dislocation—Solute dynamic model." Materials Science and Engineering: A 400-401 (July 2005): 226–30. http://dx.doi.org/10.1016/j.msea.2005.02.073.

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7

Zhang, Si Qian, Liang Mao, and Li Jia Chen. "Dynamic Strain Aging during Tensile Deformation of Extruded AZ81 Magnesium Alloy." Advanced Materials Research 652-654 (January 2013): 1937–41. http://dx.doi.org/10.4028/www.scientific.net/amr.652-654.1937.

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Serrated flow has been observed in AZ81 alloy during tensile deformation. The observed static strain ageing effect and negative strain rate sensitivity suggest that the serrated flow is due to interaction between dislocations and solute atoms, know as dynamic strain ageing (DSA). The Portevin-Le Chatelier effect is observed at temperatures between 150oC~200oC and 125oC~200oC. In the microstructure of deformed samples dislocations and twins is observed. It is suggested that the occurrence of the dynamic strain aging is associated with interactions between solute atoms and dislocations.
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8

Hörnqvist, Magnus, Ceena Joseph, Christer Persson, Jonathan Weidow, and Haiping Lai. "Dynamic strain aging in Haynes 282 superalloy." MATEC Web of Conferences 14 (2014): 16002. http://dx.doi.org/10.1051/matecconf/20141416002.

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9

Song, Yooseob, Daniel Garcia-Gonzalez, and Alexis Rusinek. "Constitutive Models for Dynamic Strain Aging in Metals: Strain Rate and Temperature Dependences on the Flow Stress." Materials 13, no. 7 (April 10, 2020): 1794. http://dx.doi.org/10.3390/ma13071794.

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A new constitutive model for Q235B structural steel is proposed, incorporating the effect of dynamic strain aging. Dynamic strain aging hugely affects the microstructural behavior of metallic compounds, in turn leading to significant alterations in their macroscopic mechanical response. Therefore, a constitutive model must incorporate the effect of dynamic strain aging to accurately predict thermo-mechanical deformation processes. The proposed model assumes the overall response of the material as a combination of three contributions: athermal, thermally activated, and dynamic strain aging stress components. The dynamic strain aging is approached by two alternative mathematical expressions: (i) model I: rate-independent model; (ii) model II: rate-dependent model. The proposed model is finally used to study the mechanical response of Q235B steel for a wide range of loading conditions, from quasi-static loading ( ε ˙ = 0.001 s − 1 and ε ˙ = 0.02 s − 1 ) to dynamic loading ( ε ˙ = 800 s − 1 and ε ˙ = 7000 s − 1 ), and across a broad range of temperatures ( 93 K − 1173 K ). The results from this work highlight the importance of considering strain-rate dependences (model II) to provide reliable predictions under dynamic loading scenarios. In this regard, rate-independent approaches (model I) are rather limited to quasi-static loading.
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10

Goretta, K. C., J. L. Routbort, and T. A. Bloom. "Dynamic strain aging and serrated flow in MnO." Journal of Materials Research 1, no. 1 (February 1986): 124–29. http://dx.doi.org/10.1557/jmr.1986.0124.

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The effects of aging on the upper yield stress τup and serrated flow have been studied in MnO single crystals at 900 °C for oxygen partial pressures ρO2 of 10−11 and 10−7 Pa. Aging initially increases τup as a consequence of segregation of aliovalent impurities to dislocations for both ρO2 values. For long aging times and ρO2 = 10-11 Pa, serrated flow accompanied by solute softening is observed. The data fit predictions of a Portevin-Le Chatelier model for serrations, but with impurity atmospheres causing softening instead of hardening. This is believed to result from changes in local defect equilibria caused by segregation of impurities with valences greater than two to dislocations.
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11

Guo, Wei Guo. "Dynamic Strain Aging during the Plastic Flow of Metals." Key Engineering Materials 340-341 (June 2007): 823–28. http://dx.doi.org/10.4028/www.scientific.net/kem.340-341.823.

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In the present paper, in order to better understand the third type “dynamic strain aging” occurring during the plastic flow of metals, the uniaxial compressive experimental data ever obtained in University of California, San Diego using an Instron servo-hydraulic testing machine and the Hopkinson technique are systematically analysed. These experimental data cover the plastic flow stress of several fcc, hcp, bcc polycrystalline materials and several alloys at a broad range of temperatures (77K – 1,100K) and strain rates (0.001/s – 10,000/s). In analysis, the appearing region of the “dynamic strain aging ” under different temperatures and strain rates are respectively plotted by the curves of stress vs temperature, and stress vs strain for fcc, hcp and bcc metals. The results show that: (1) this third type “dynamic strain aging ” occurs in all hcp, bcc and fcc polycrystalline or alloy materials, and there are different profiles of stress-strain curve; (2) the “dynamic strain aging ”occurs in a matching coincidence of the temperature and strain rate, its temperature region will shift to higher region with increasing strain rates; (3) bcc materials do not have an initial pre-straining strain as the onset of work-hardness rate change for the “dynamic strain aging ”; and (4) based on the explanations of dynamic strain aging with serration curves (Portevin-Lechatelier effect) and other explaining mechanisms of references, The mechanism of third DSA is thought as the rapid/continuous formation of the solute atmospheres at the mobile dislocation core by the pipe diffusion along vast collective forest dislocations to result in a continuous rise curve of flow stress. Finally, several conclusions are also presented.
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12

Chen, Li Jia, Jia Li, Feng Li, and Xin Wang. "Dynamic Strain Aging Induced by Cyclic Deformation in Two Magnesium Alloys." Advanced Materials Research 299-300 (July 2011): 90–93. http://dx.doi.org/10.4028/www.scientific.net/amr.299-300.90.

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Cyclic deformation for two magnesium alloys AZ91 and AM50 with different processing status has been performed under total strain amplitude control mode and at room temperature. A serrated flow can be observed in both tensile and compressive directions of the stress-strain hysteresis loop for as-extruded AZ91 and AM50 magnesium alloys. It means that the so-called dynamic strain aging occurs during cyclic deformation. In addition, the dynamic strain aging phenomenon can also be observed in two extruded magnesium alloys subjected to aging treatment as well as the AZ91 alloy subjected to solution treatment. However, the dynamic strain aging seems not to take place in the extruded AM50 alloy subjected to solution treatment because there exists no significant serrated flow behavior in either compressive or tensile direction of the stress-strain hysteresis loop. It is suggested that the occurrence of the dynamic strain aging is associated with collective behavior of many mobile dislocations as well as interactions between solute atoms and dislocations.
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13

KOUSHIMA, Motohiko, and Sei MIURA. "Dynamic Strain-aging in Fe-30%Cr Alloys." Journal of the Society of Materials Science, Japan 54, no. 5 (2005): 529–33. http://dx.doi.org/10.2472/jsms.54.529.

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14

Voyiadjis, George Z., Yooseob Song, and Alexis Rusinek. "Constitutive model for metals with dynamic strain aging." Mechanics of Materials 129 (January 2019): 352–60. http://dx.doi.org/10.1016/j.mechmat.2018.12.012.

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15

Gündüz, S. "Dynamic strain aging effects in niobium microalloyed steel." Ironmaking & Steelmaking 29, no. 5 (October 2002): 341–46. http://dx.doi.org/10.1179/030192302225004575.

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16

Aboulfadl, H., J. Deges, P. Choi, and D. Raabe. "Dynamic strain aging studied at the atomic scale." Acta Materialia 86 (March 2015): 34–42. http://dx.doi.org/10.1016/j.actamat.2014.12.028.

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17

Kumar, Subodh, Erwin Pink, and Robert Grill. "Dynamic strain aging in a tungsten heavy metal." Scripta Materialia 35, no. 9 (November 1996): 1047–52. http://dx.doi.org/10.1016/1359-6462(96)00262-x.

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18

Sevast'yanov, E. S., and P. N. Kireev. "Dynamic strain aging of powdered alloys Cu-Ti." Soviet Powder Metallurgy and Metal Ceramics 25, no. 2 (February 1986): 143–47. http://dx.doi.org/10.1007/bf00805614.

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19

Weaver, M. L., R. D. Noebe, and M. J. Kaufman. "Observations of dynamic strain aging in polycrystalline NiAl." Intermetallics 4, no. 8 (January 1996): 593–600. http://dx.doi.org/10.1016/0966-9795(96)00045-3.

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20

Zhao, Shuang Zan, Xing Wang Cheng, and Fu Chi Wang. "Study on Dynamic Mechanical Response of TC21 Alloy." Applied Mechanics and Materials 88-89 (August 2011): 674–78. http://dx.doi.org/10.4028/www.scientific.net/amm.88-89.674.

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Some results of an experimental study on high strain rate deformation of TC21 alloy are discussed in this paper. Cylindrical specimens of the TC21 alloys both in binary morphology and solution and aging morphology were subjected to high strain rate deformation by direct impact using a Split Hopkinson Pressure Bar. The deformation process is dominated by both thermal softening effect and strain hardening effect under high strain rate loading. Thus the flow stress doesn’t increase with strain rate at the strain hardening stage, while the increase is obvious under qusi-static compression. Under high strain rate, the dynamic flow stress is higher than that under quasi-static and dynamic flow stress increase with the increase of the strain rate, which indicates the strain rate hardening effect is great in TC21 alloy. The microstructure affects the dynamic mechanical properties of TC21 titanium alloy obviously. Under high strain rate, the solution and aging morphology has higher dynamic flow stress while the binary morphology has better plasticity and less prone to be instability under high strain rate condition. Shear bands were found both in the solution and aging morphology and the binary morphology.
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21

Yuan, Dan, Lei Wang, Yang Liu, Xiu Song, and Jia Hua Liu. "Effects of Strain Rate on Dynamic Strain Aging of SA508-III Steel." Materials Science Forum 788 (April 2014): 334–39. http://dx.doi.org/10.4028/www.scientific.net/msf.788.334.

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The dynamic strain aging (DSA) behavior of SA508-III steel was evaluated through tensile tests with different strain rates from 10-4 to 10-1s-1 at 350°C. The OM, SEM and TEM were carried out to observe the microstructures and fracture morphologies of the steel. The results show that the serrated flows appear in the stress-strain curves when the strain rate is between 10-3~10-2s-1, indicating that DSA occurs. Under the strain rate range, the tensile strength increases and the elongation and the reduction of area decrease. However, the fracture surface of the steel after tensile tests is still ductile. DSA in SA508-III steel at the strain rates from10-3 to 10-2s-1 is mainly caused by the interaction between the internal solute atoms and dislocations, which leads to the dislocations multiplication and the formation of sub-grain boundaries and dislocation cell structure.
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22

Béda, Peter B. "On the Role of Phenomenology and Dislocations in Modelling of Portevin - Le Chatelier Effect." Materials Science Forum 729 (November 2012): 138–43. http://dx.doi.org/10.4028/www.scientific.net/msf.729.138.

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A strange self-sustained oscillation in plastic uniaxial tension of various materials is called the Portevin Le Chatelier (PLC) effect. In modelling PLC dynamic strain aging is the common way of explanation. It is based mainly on dislocation dynamics. Experimental studies show the negative strain rate dependence (NRS) is always present at PLC. By using continuum mechanics and dynamical systems theory we find that NRS is the essential reason of it.
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23

Queiroz, R. R. U., F. G. G. Cunha, and B. M. Gonzalez. "Study of dynamic strain aging in dual phase steel." Materials Science and Engineering: A 543 (May 2012): 84–87. http://dx.doi.org/10.1016/j.msea.2012.02.050.

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24

Robinson, J. M., and M. P. Shaw. "Microstructural and mechanical influences on dynamic strain aging phenomena." International Materials Reviews 39, no. 3 (January 1994): 113–22. http://dx.doi.org/10.1179/imr.1994.39.3.113.

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25

Wagner, D., C. Prioul, and D. François. "Sensitivity to dynamic strain aging in C—Mn steels." Journal of Alloys and Compounds 211-212 (September 1994): 132–35. http://dx.doi.org/10.1016/0925-8388(94)90465-0.

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26

Lopes, Felipe Perissé D., Chia Hui Lu, Shiteng Zhao, Sergio N. Monteiro, and Marc A. Meyers. "Room Temperature Dynamic Strain Aging in Ultrafine-Grained Titanium." Metallurgical and Materials Transactions A 46, no. 10 (July 24, 2015): 4468–77. http://dx.doi.org/10.1007/s11661-015-3061-7.

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27

Song, Yooseob, and George Z. Voyiadjis. "Constitutive modeling of dynamic strain aging for HCP metals." European Journal of Mechanics - A/Solids 83 (September 2020): 104034. http://dx.doi.org/10.1016/j.euromechsol.2020.104034.

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28

Schlipf, J. "On the kinetics of static and dynamic strain aging." Scripta Metallurgica et Materialia 31, no. 7 (October 1994): 909–14. http://dx.doi.org/10.1016/0956-716x(94)90501-0.

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29

Gross, T. S., V. K. Mathews, R. J. De Angelis, and K. Okazaki. "Dynamic strain aging in Czochralski-grown silicon single crystals." Materials Science and Engineering: A 117 (September 1989): 75–82. http://dx.doi.org/10.1016/0921-5093(89)90088-9.

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30

Berdin, C., and H. Wang. "Local approach to ductile fracture and dynamic strain aging." International Journal of Fracture 182, no. 1 (May 12, 2013): 39–51. http://dx.doi.org/10.1007/s10704-013-9856-x.

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31

Peng, Guangwei, and Xueping Gan. "Re-aging behavior of Cu–15Ni–8Sn alloy pretreated by dynamic strain aging." Materials Science and Engineering: A 752 (April 2019): 18–23. http://dx.doi.org/10.1016/j.msea.2019.02.073.

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32

Bayramin, Berkay, Caner Şimşir, and Mert Efe. "Dynamic strain aging in DP steels at forming relevant strain rates and temperatures." Materials Science and Engineering: A 704 (September 2017): 164–72. http://dx.doi.org/10.1016/j.msea.2017.08.006.

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33

Cheng, Jingyi, and Sia Nemat-Nasser. "A model for experimentally-observed high-strain-rate dynamic strain aging in titanium." Acta Materialia 48, no. 12 (July 2000): 3131–44. http://dx.doi.org/10.1016/s1359-6454(00)00124-5.

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34

Matsuoka, Saiji, Kei Sakata, Susumu Satoh, and Toshiyoki Kato. "Development of a {111} Recrystallization Texture Associated With Dynamic Strain Aging During Hot Rolling in the Ferrite Region." Textures and Microstructures 22, no. 2 (January 1, 1993): 113–26. http://dx.doi.org/10.1155/tsm.22.113.

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Hot rolling in the ferrite region is applied in an extra-low C sheet steel without cold rolling by employing dynamic strain aging. When the amount of solute C is about 10 ppm before rolling, the r-value and {222} intensity ratio of sheet steel annealed after rolling are maxima at the rolling temperature of 773K, during which dynamic strain aging occurs. The {222} residual strain in the specimen rolled at 773K is higher than that in specimens rolled at other temperatures. It is proposed that dynamic strain aging would provide high stored energy in the {111} component of an as-rolled specimen, with the result that the region of high stored energy would recover and nucleate rapidly so that a strong {111} recrystallization texture develops.
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35

Rezende, Monica Costa, Leonardo Sales Araújo, Sinara Borborema Gabriel, Jean Dille, and Luiz Henrique de Almeida. "Observations on Dynamic Strain Aging Manifestation in Inconel 718 Superalloy." Materials Science Forum 930 (September 2018): 390–94. http://dx.doi.org/10.4028/www.scientific.net/msf.930.390.

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The manifestation of dynamic strain aging (DSA) in Inconel 718 is reported in this work. Analysis were performed in the material with different microstructures resulting from solution anneal and aging treatment. Tensile tests were made under secondary vacuum with temperature ranging between 200 and 950°C and strain rates of 3.2 x 10-3 to 3.2 x 10-5 s-1. Results showed the range of DSA occurrence. Analysis indicates that at lower temperatures, from approximately 200 to 450°C, serrations are controlled by the diffusion of carbon. At higher temperatures, until 800°C, DSA coincided with the occurrence of other thermally activated phenomena: dynamic precipitation, especially γ’’, and Oxidation Assisted Intergranular Cracking (OAIC). It was observed that competitive phenomena affect DSA manifestation directly due to the availability of niobium in solid solution.
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36

Liu, Hai Jun, Ding Yi Zhu, Xian Peng, Zhen Ming Hu, and Ming Jie Wang. "Dynamic Strain Aging in the Fe-Mn-Cu-C TWIP Steels." Advanced Materials Research 668 (March 2013): 861–64. http://dx.doi.org/10.4028/www.scientific.net/amr.668.861.

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Strain rate jump tests were performed on the Fe-Mn-Cu-C TWIP Steels to determine the strain rate sensitivity, and serrated plastic flow was observed in the stress-strain curves during tensile tests at different constant strain rates ranging from 2.5×10-4S-1 to 2.5×10-2S-1. The Fe-Mn-Cu-C TWIP Steels exhibit high work hardening rate and outstanding mechanical properties, The excellent mechanical properties are attributed to dynamic strain aging(DSA) effect, which result from the interaction between Mn(Cu)-C atom atmosphere, C-vacancy, C-C pairs and moving dislocations.
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37

Lin, Na, Kai Huai Yang, Shao Feng Zeng, and Wen Zhe Chen. "Study on Dynamic Strain Aging Phenomenon of AZ91D Magnesium Alloy." Advanced Materials Research 472-475 (February 2012): 2962–65. http://dx.doi.org/10.4028/www.scientific.net/amr.472-475.2962.

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Tensile experiment of AZ91D magnesium alloy was carried out and serrated flow was apparent throughout the deformation history. Dynamic strain aging (DSA) occurs when the AZ91D magnesium alloy treated by solid solution treatment has been deformed at a set range of strain rates (1.11×10-4 s-1 to1.67×10-3 s-1) and a certain range temperatures (248 K to 423 K). The critical plastic strain εc was observed to increase with increasing strain rates but decrease with increasing temperature. The diffusing activation energy of solute atoms during the DSA occurring in AZ91D magnesium alloy is 140.8 kJ/mol by calculating, which is correspondence match with the diffusing activation energy of Al solute atoms in Mg matrix. Therefore, the micro-mechanism of DSA in the alloy is believed that the Al atoms in solid solution gather around dislocations to form Cottrell solute atmospheres by vacant diffusion and then pin the moving dislocations.
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38

Cui, C. Y., Y. F. Gu, Y. Yuan, and H. Harada. "Dynamic strain aging in a new Ni–Co base superalloy." Scripta Materialia 64, no. 6 (March 2011): 502–5. http://dx.doi.org/10.1016/j.scriptamat.2010.11.025.

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39

Kim, Jin Weon, and In Sup Kim. "Investigation of dynamic strain aging in SA106 Gr.C piping steel." Nuclear Engineering and Design 172, no. 1-2 (July 1997): 49–59. http://dx.doi.org/10.1016/s0029-5493(97)00045-9.

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40

Peng, Kaiping, Wenzhe Chen, and Kuangwu Qian. "Study on dynamic strain aging phenomenon of 3004 aluminum alloy." Materials Science and Engineering: A 415, no. 1-2 (January 2006): 53–58. http://dx.doi.org/10.1016/j.msea.2005.08.216.

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41

Miyazawa, Takeshi, Takuya Nagasaka, Yoshimitsu Hishinuma, Takeo Muroga, Yanfen Li, Yuhki Satoh, Sawoong Kim, and Hiroaki Abe. "Effect of yttrium on dynamic strain aging of vanadium alloys." Journal of Nuclear Materials 442, no. 1-3 (November 2013): S341—S345. http://dx.doi.org/10.1016/j.jnucmat.2013.03.091.

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42

Kohandehghan, A. R., A. R. Sadeghi, J. M. Akhgar, and S. Serajzadeh. "Investigation into dynamic strain aging behaviour in high carbon steel." Ironmaking & Steelmaking 37, no. 2 (February 2010): 155–60. http://dx.doi.org/10.1179/174328109x461400.

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43

Kang, Sung Sik, and In Sup Kim. "Dynamic Strain-Aging Effect on Fracture Toughness of Vessel Steels." Nuclear Technology 97, no. 3 (March 1992): 336–43. http://dx.doi.org/10.13182/nt92-a34641.

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44

de Almeida, L. H., I. Le May, and P. R. O. Emygdio. "Mechanistic Modeling of Dynamic Strain Aging in Austenitic Stainless Steels." Materials Characterization 41, no. 4 (October 1998): 137–50. http://dx.doi.org/10.1016/s1044-5803(98)00031-x.

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45

Shin, Jong-Ho, Jae Hoon Jang, Sung-Dae Kim, Seong-Jun Park, and Jehyun Lee. "Dynamic strain aging in Fe-Mn-Al-C lightweight steel." Philosophical Magazine Letters 100, no. 7 (June 1, 2020): 355–64. http://dx.doi.org/10.1080/09500839.2020.1768603.

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46

Gupta, C., J. K. Chakravartty, and S. Banerjee. "Microstructure and dynamic strain aging phenomena in two structural steels." Materials Science and Technology 27, no. 6 (June 2011): 1007–12. http://dx.doi.org/10.1179/026708310x12815992418418.

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47

Bouchaud, E., L. Kubin, and H. Octor. "Ductility and dynamic strain aging in rapidly solidified aluminum alloys." Metallurgical Transactions A 22, no. 5 (May 1991): 1021–28. http://dx.doi.org/10.1007/bf02661095.

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48

Kim, I. S., and S. S. Kang. "Dynamic strain aging in SA508-class 3 pressure vessel steel." International Journal of Pressure Vessels and Piping 62, no. 2 (January 1995): 123–29. http://dx.doi.org/10.1016/0308-0161(95)93969-c.

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49

Jae-Kyung, Yi, Park Heung-Bae, Park Gi-Sung, and Lee Byong-Whi. "Yielding and dynamic strain aging behavior of Zircaloy-4 tube." Journal of Nuclear Materials 189, no. 3 (August 1992): 353–61. http://dx.doi.org/10.1016/0022-3115(92)90388-2.

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50

Senkov, O. N., and J. J. Jonas. "Dynamic strain aging and hydrogen-induced softening in alpha titanium." Metallurgical and Materials Transactions A 27, no. 7 (July 1996): 1877–87. http://dx.doi.org/10.1007/bf02651937.

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