期刊
SMART MATERIALS AND STRUCTURES
卷 30, 期 4, 页码 -出版社
IOP PUBLISHING LTD
DOI: 10.1088/1361-665X/abea03
关键词
amorphous materials; electron microscopy; phase transformation; shear band; storage modulus; stress relaxation
资金
- Universiti Teknologi Malaysia (UTM) under Trans-disciplinary Research Grant (TDR) [06G77]
- Universiti Teknologi Malaysia (UTM) under Professional Development Research University (PDRU) [05E21]
- Universitas Sebelas Maret
This study aimed to investigate the microscopic transformation and deformation ability of magnetorheological elastomer within the elastic region, revealing that the storing energy capacity and predominantly elastic behavior of MRE are influenced by dynamic shearing.
The characteristics and behaviors of magnetorheological elastomer (MRE) within the elastic region are significantly important to demonstrate potentiality toward infinitesimal deformation in various applications. As MRE dynamically shears within an elastic region at constant small deformation, its significant consequence has long been a pending topic, hampered partly by the lack of empirical evidence. Therefore, this paper aimed to investigate the onset microscopically transformation of the MRE sample precipitated to storage modulus behavior under stress relaxation conditions. To achieve the aim, MRE with 70 wt% carbonyl iron particles was dynamically sheared at 1 Hz frequency and 0.01% strain for a designated period of test duration. The morphology evaluation of the sheared sample disclosed the development of permanent microplasticity in a very narrow region of shear bands. The deformation adequately reduced the storing energy ability of the MRE at a dominantly elastic behavior. The results revealed that the ability of MRE to store deformation energy slightly reduced by 0.3%-0.5% for the 2000 s test interval. This interesting onset phenomenon was successfully achieved, and the establishment of this early-stage deformation was undeniably important as preliminary data for catastrophic investigation at a longer duration.
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