Microstructural Study of the Phase Transformations Upon Cooling to Room Temperature of High Mn Steels

WEI-CHUN CHENG; TUNG-YI LIN

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Microstructural Study of the Phase Transformations Upon Cooling to Room Temperature of High Mn Steels

机译：高锰钢冷却至室温时的相变组织研究

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The phase transformations of high Mn steels during cooling have been characterized in this study. Widmanstatten plates occur in the austenite matrix upon cooling the steels from 1373 K (1100 °C). The Widmanstatten plates are composed of not only the hexagonal close-packed e-martensite but also the face-centered cubic (FCC) micro-twins. The formation mechanism of the Widmanstatten phases is probably various stacking faults induced from Shockley partial dislocations in the austenite. The e-martensitic plates, along with the K-carbides, were observed in a Mn-Al steel at 873 K (600 °C). As most of the FCC matrix has transformed to K-carbides, the partial dislocations neighboring e-martensitic plates could not glide. The e-martensite retained in the transformed matrix is the strongest evidence to support the above mechanism.

机译：这项研究已经表征了高锰钢在冷却过程中的相变。在将钢从1373 K（1100°C）冷却后，奥氏体基体中会出现Widmanstatten板。 Widmanstatten板不仅由密堆积的六角形马氏体组成，而且由面心立方（FCC）微孪晶组成。 Widmanstatten相的形成机制可能是由于奥氏体中Shockley部分位错引起的各种堆垛层错。在873 K（600°C）的Mn-Al钢中观察到e马氏体板以及K碳化物。由于大多数FCC基质已转变为K碳化物，因此邻近电子马氏体板的部分位错无法滑动。保留在转化基质中的电子马氏体是支持上述机制的最有力证据。

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《Metallurgical and Materials Transactions, A. Physical Metallurgy and Materials Science》 |2012年第6期|共8页
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WEI-CHUN CHENG; TUNG-YI LIN;
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Microstructural Study of the Phase Transformations Upon Cooling to Room Temperature of High Mn Steels

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