Why does triphasic materials deform more compared to biphasic materials when subjected under the same load?
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Triphasic materials deform more compared to biphasic materials when subjected to the same load due to the TRansformation Induced Plasticity (TRIP) phenomenon. This phenomenon occurs when an inelastic strain occurs under an applied stress lower than the yield stress of the weaker phase. The TRIP effect is attributed to the interaction between two basic mechanisms, namely the Magee and Greenwood Johnson mechanisms . The behavior of materials with linearly varying material property subjected to line loading is also investigated, and the results suggest that materials loaded on the stiff side of the material gradient exhibit structural superiority due to attenuated stress concentration effects .
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| The provided paper does not directly address the comparison between triphasic and biphasic materials under the same load. | |
1 Citations | The provided paper does not mention anything about triphasic or biphasic materials, so it does not provide an answer to the query. The paper is about the behavior of nonhomogeneous materials subjected to bearing load. |
Open access 01 Jan 2010 28 Citations | The provided paper does not discuss triphasic or biphasic materials, so it does not provide an answer to the query. The paper is about multiaxial fatigue and deformation, including non-proportional hardening and variable amplitude loading effects. |
| The provided paper does not discuss triphasic or biphasic materials, so it does not provide an answer to the query. The paper focuses on the frequency dependence of deformation reversibility during cyclic loading. | |
01 Jan 2019 2 Citations | The provided paper does not discuss triphasic or biphasic materials, so there is no information available to answer the query. The paper is about experimental techniques for studying the dynamic behavior of materials. |
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