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Journal articles on the topic 'Micropillar compression'

Author: Grafiati
Published: 4 June 2021
Last updated: 27 July 2025

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1

Tian, Gao Feng, Yang Chen, Bin Gan, Yan Yang, and Jin Wen Zou. "Microstructure-Dependent Deform Behavior of a Polycrystalline Ni-Based Superalloy Based on Micropillar Compression." Materials Science Forum 944 (January 2019): 25–32. http://dx.doi.org/10.4028/www.scientific.net/msf.944.25.

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A study was carried out to determine the deform behavior in a polycrystalline Ni-based superalloy based on micropillar compression tests. Three different heat treatments of this alloy were evaluated by systematically controlling the cooling rate from the supersolvus solutioning step, in order to examine the effect of γ' microstructure on the CRSS (Critical Resolved Shear Stress). It is shown that the γ' precipitates have the marked effect on the deform behavior of micropillar, as the size of the secondary γ' in the general microstructure decreased, the CRSS were increased; SEM and TEM examinat
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2

Sly, Michael K., Arashdeep S. Thind, Rohan Mishra, Katharine M. Flores, and Philip Skemer. "Low-temperature rheology of calcite." Geophysical Journal International 221, no. 1 (2019): 129–41. http://dx.doi.org/10.1093/gji/ggz577.

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SUMMARY Low-temperature plastic rheology of calcite plays a significant role in the dynamics of Earth's crust. However, it is technically challenging to study plastic rheology at low temperatures because of the high confining pressures required to inhibit fracturing. Micromechanical tests, such as nanoindentation and micropillar compression, can provide insight into plastic rheology under these conditions because, due to the small scale, plastic deformation can be achieved at low temperatures without the need for secondary confinement. In this study, nanoindentation and micropillar compression
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3

Shiau, Ching-Heng, Miguel Pena, Yongchang Li, et al. "Micropillar Compression of Additively Manufactured 316L Stainless Steels after 2 MeV Proton Irradiation: A Comparison Study between Planar and Cross-Sectional Micropillars." Metals 12, no. 11 (2022): 1843. http://dx.doi.org/10.3390/met12111843.

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A micropillar compression study with two different techniques was performed on proton-irradiated additively manufactured (AM) 316L stainless steels. The sample was irradiated at 360 °C using 2 MeV protons to 1.8 average displacement per atom (dpa) in the near-surface region. A comparison study with mechanical test and microstructure characterization was made between planar and cross-sectional pillars prepared from the irradiated surface. While a 2 MeV proton irradiation creates a relatively flat damage zone up to 12 µm, the dpa gradient by a factor of 2 leads to significant dpa uncertainty alo
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4

Shahbeyk, Voyiadjis, Habibi, Astaneh, and Yaghoobi. "Review of Size Effects during Micropillar Compression Test: Experiments and Atomistic Simulations." Crystals 9, no. 11 (2019): 591. http://dx.doi.org/10.3390/cryst9110591.

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The micropillar compression test is a novel experiment to study the mechanical properties of materials at small length scales of micro and nano. The results of the micropillar compression experiments show that the strength of the material depends on the pillar diameter, which is commonly termed as size effects. In the current work, first, the experimental observations and theoretical models of size effects during micropillar compression tests are reviewed in the case of crystalline metals. In the next step, the recent computer simulations using molecular dynamics are reviewed as a powerful too
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5

Wasmer, K., T. Wermelinger, A. Bidiville, R. Spolenak, and J. Michler. "In situ compression tests on micron-sized silicon pillars by Raman microscopy—Stress measurements and deformation analysis." Journal of Materials Research 23, no. 11 (2008): 3040–47. http://dx.doi.org/10.1557/jmr.2008.0363.

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Mechanical properties of silicon are of high interest to the microelectromechanical systems community as it is the most frequently used structural material. Compression tests on 8 μm diameter silicon pillars were performed under a micro-Raman setup. The uniaxial stress in the micropillars was derived from a load cell mounted on a microindenter and from the Raman peak shift. Stress measurements from the load cell and from the micro-Raman spectrum are in excellent agreement. The average compressive failure strength measured in the middle of the micropillars is 5.1 GPa. Transmission electron micr
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6

Huskins, Emily L., Zachary C. Cordero, Christopher A. Schuh, and Brian E. Schuster. "Micropillar compression testing of powders." Journal of Materials Science 50, no. 21 (2015): 7058–63. http://dx.doi.org/10.1007/s10853-015-9260-1.

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7

Klímek, Petr, Václav Sebera, Darius Tytko, Martin Brabec, and Jaroslav Lukeš. "Micromechanical properties of beech cell wall measured by micropillar compression test and nanoindentation mapping." Holzforschung 74, no. 9 (2020): 899–904. http://dx.doi.org/10.1515/hf-2019-0128.

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AbstractWood exhibits very different behavior and properties at different scales. One important scale is the cell wall (CW) that is commonly tested by nanoindentation. Common nanoindentation provides important insight into the material but has limitations because it does not apply uniaxial stress and provides data from single spots. Therefore, the aim was to examine beech CW using two state-of-the-art techniques: micropillar compression (MCo) and nanoindentation mapping (NIP). The mean strength of the beech CW was found to be about 276 MPa and the mean yield stress was 183 MPa. These values we
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8

Takata, N., H. Ghassemi-Armaki, Y. Terada, M. Takeyama, and S. Kumar. "Effect of Dislocation Sources on Slip in Fe2Nb Laves Phase with Ni in Solution." MRS Proceedings 1516 (2012): 269–74. http://dx.doi.org/10.1557/opl.2012.1566.

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ABSTRACTWe have examined the compression response of a ternary Fe2Nb Laves phase by deforming micropillars with a diameter of ~2 μm produced by focused ion beam milling from a two-phase Fe-15Nb-40Ni (at.%) ternary alloy consisting of the Laves phase and γ-Fe. The Laves phase micropillars exhibit high strength of about 6 GPa (of the order of the theoretical shear strength of the material), followed by a burst of plastic strain and shear failure on the basal plane. If dislocation sources are introduced on a non-basal plane in the micropillars by nanoindentation prior to compression, yielding occ
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9

Camposilvan, Erik, and Marc Anglada. "Micropillar compression inside zirconia degraded layer." Journal of the European Ceramic Society 35, no. 14 (2015): 4051–58. http://dx.doi.org/10.1016/j.jeurceramsoc.2015.04.017.

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10

Singh, D. R. P., N. Chawla, G. Tang, and Y. L. Shen. "Micropillar compression of Al/SiC nanolaminates." Acta Materialia 58, no. 20 (2010): 6628–36. http://dx.doi.org/10.1016/j.actamat.2010.08.025.

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11

Jun, Tea-Sung. "Local strain rate sensitivity of α+β phases within dual-phase Ti alloys". Journal of Physics: Conference Series 2169, № 1 (2022): 012040. http://dx.doi.org/10.1088/1742-6596/2169/1/012040.

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Abstract Using in-situ micropillar compression, the local strain rate sensitivity in Ti6242 and Ti6246 has been investigated to strengthen our understanding on the rate- and slip system-sensitive deformation of dual-phase Ti alloys. Electron backscatter diffraction (EBSD) was used to find target grains anticipating basal and primatic slip activities under compression test. Micropillars with similar α orientation and incomparable β morphology were made by a focused ion beam (FIB). Strain rate sensitivity (SRS) was determined based on the constant strain rate method (CSRM). The marked difference
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12

Maeder, X., W. M. Mook, C. Niederberger, and J. Michler. "Quantitative stress/strain mapping during micropillar compression." Philosophical Magazine 91, no. 7-9 (2011): 1097–107. http://dx.doi.org/10.1080/14786435.2010.505178.

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13

Korte, S., and W. J. Clegg. "Micropillar compression of ceramics at elevated temperatures." Scripta Materialia 60, no. 9 (2009): 807–10. http://dx.doi.org/10.1016/j.scriptamat.2009.01.029.

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14

Schoell, Ryan, Ce Zheng, Khalid Hattar, and Djamel Kaoumi. "In Situ Micropillar Compression of Irradiated HT9." Microscopy and Microanalysis 26, S2 (2020): 2420–22. http://dx.doi.org/10.1017/s1431927620021522.

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15

Kuroda, Mitsutoshi. "Higher-order gradient effects in micropillar compression." Acta Materialia 61, no. 7 (2013): 2283–97. http://dx.doi.org/10.1016/j.actamat.2012.12.038.

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16

Paccou, Elie, Benoît Tanguy, and Marc Legros. "Micropillar compression study of Fe-irradiated 304L steel." Scripta Materialia 172 (November 2019): 56–60. http://dx.doi.org/10.1016/j.scriptamat.2019.07.007.

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17

Howie, Philip R., Sandra Korte, and William J. Clegg. "Fracture modes in micropillar compression of brittle crystals." Journal of Materials Research 27, no. 1 (2011): 141–51. http://dx.doi.org/10.1557/jmr.2011.256.

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18

Lotfian, S., M. Rodríguez, K. E. Yazzie, N. Chawla, J. Llorca, and J. M. Molina-Aldareguía. "High temperature micropillar compression of Al/SiC nanolaminates." Acta Materialia 61, no. 12 (2013): 4439–51. http://dx.doi.org/10.1016/j.actamat.2013.04.013.

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19

Tasan, C. C., J. P. M. Hoefnagels, and M. G. D. Geers. "A Micropillar Compression Methodology for Ductile Damage Quantification." Metallurgical and Materials Transactions A 43, no. 3 (2011): 796–801. http://dx.doi.org/10.1007/s11661-011-1021-4.

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20

Zhang, Wei, Hongcai Xie, Zhichao Ma, Hongwei Zhao, and Luquan Ren. "Graphene Oxide-Induced Substantial Strengthening of High-Entropy Alloy Revealed by Micropillar Compression and Molecular Dynamics Simulation." Research 2022 (August 25, 2022): 1–10. http://dx.doi.org/10.34133/2022/9839403.

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Plastic deformation mechanisms at micro/nanoscale of graphene oxide-reinforced high-entropy alloy composites (HEA/GO) remain unclear. In this study, small-scale mechanical behaviors were evaluated for HEA/GO composites with 0.0 wt.%, 0.3 wt.%, 0.6 wt.%, and 1.0 wt.% GO, consisting of compression testing on micropillar and molecular dynamics (MD) simulations on nanopillars. The experimental results uncovered that the composites exhibited a higher yield strength and flow stress compared with pure HEA micropillar, resulting from the GO reinforcement and grain refinement strengthening. This was al
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21

Gubicza, Jenő, Garima Kapoor, Dávid Ugi, László Péter, János L. Lábár, and György Radnóczi. "Micropillar Compression Study on the Deformation Behavior of Electrodeposited Ni–Mo Films." Coatings 10, no. 3 (2020): 205. http://dx.doi.org/10.3390/coatings10030205.

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The influence of Mo addition on the compression behavior of Ni films was studied by micropillar deformation tests. Thus, films with low (0.4 at.%) and high (5.3 at.%) Mo contents were processed by electrodeposition and tested by micropillar compression up to the plastic strain of about 0.26. The microstructures of the films before and after compression were studied by transmission electron microscopy. It was found that the as-deposited sample with high Mo concentration has a much lower grain size (~26 nm) than that for the layer with low Mo content (~240 nm). In addition, the density of lattic
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22

Zhao, Yongfeng, Arun Sundar S. Singaravelu, Xia Ma, Xiangfa Liu, and Nikhilesh Chawla. "Mechanical properties of Al3BC by nanoindentation and micropillar compression." Materials Letters 264 (April 2020): 127361. http://dx.doi.org/10.1016/j.matlet.2020.127361.

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23

Jiang, L., and N. Chawla. "Mechanical properties of Cu6Sn5 intermetallic by micropillar compression testing." Scripta Materialia 63, no. 5 (2010): 480–83. http://dx.doi.org/10.1016/j.scriptamat.2010.05.009.

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24

Fehlemann, Niklas C., Angelica Medina, Subin Lee, Christoph Kirchlechner, and Sebastian Münstermann. "Crystal plasticity parameter identification via statistical relevant micropillar compression." Acta Materialia 297 (September 2025): 121321. https://doi.org/10.1016/j.actamat.2025.121321.

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25

An, Woojin, Jaewon Heo, Dongchan Jang, et al. "Microstructural Evolution of Al–Zn–Mg–Cu Alloys in Accordance with Homogenization Time." Journal of Nanoscience and Nanotechnology 20, no. 11 (2020): 6890–96. http://dx.doi.org/10.1166/jnn.2020.18808.

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The microstructural evolution of Al–Zn–Mg–Cu alloys has been investigated for the homogenization time effect on the texture, grain orientation and dislocation density. The Al–Zn–Mg–Cu alloys were casted and homogenized for 4, 8, 16 and 24 hours. Electron backscatter diffraction (EBSD) analysis was conducted to characterize the microstructural behavior. Micropillars were fabricated using focused ion beam (FIB) milling in grains of specific crystallographic orientations. Coarse precipitations in the grain boundaries are S (Al2CuMg) and T (Al2Mg3Zn3) phases verified by scanning electron microscop
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26

Kaede, K., A. Jäger, V. Gärtnerová, C. Takushima, T. Yamamuro, and S. Tsurekawa. "Measurement of Local Mechanical Properties of T91 Steel Corroded by Molten Lead-Bismuth Eutectic Alloy via Micropillar Compression Test." MRS Advances 3, no. 8-9 (2018): 419–25. http://dx.doi.org/10.1557/adv.2018.36.

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ABSTRACTT91 ferritic/martensitic (F/M) steel is an expected structural material candidate for Gen IV liquid lead-bismuth cooled nuclear reactors. However, molten lead-bismuth eutectic alloy (mLBE) often causes liquid-metal embrittlement (LME) of F/M steels. Although prior austenite grain boundaries and martensite block boundaries were reported to be preferential sites for LME, the mechanism of LME in a T91/LBE couple is yet to be comprehensively understood. In this paper, the effect of mLBE on T91 steel was investigated using micropillar compression tests. mLBE corrosion was found to cause a s
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27

Konstantinidis, Avraam A., Konstantinos Michos, and Elias C. Aifantis. "On the correct interpretation of compression experiments of micropillars produced by a focused ion beam." Journal of the Mechanical Behavior of Materials 25, no. 3-4 (2016): 83–87. http://dx.doi.org/10.1515/jmbm-2016-0009.

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AbstractThe modest goal of this short note is to shed some light on the correct interpretation of micro/nanopillar compression experiments. We propose a modification of the way the stress-strain response in such experiments is calculated, aiming at answering open questions pertaining to discrepancies between the elastic moduli values calculated through micropillar compression experiments with those of the bulk materials, as well as the brittle-to-ductile transition in bulk metallic glasses (BMGs) when the size of the pillars is reduced below a certain threshold value.
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28

Gu, Ting, Ping Cheng, Su Wang, et al. "Mechanical property evaluation of TSV-Cu micropillar by compression method." Electronic Materials Letters 10, no. 4 (2014): 851–55. http://dx.doi.org/10.1007/s13391-014-3286-4.

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29

Kiener, D., P. J. Guruprasad, S. M. Keralavarma, G. Dehm, and A. A. Benzerga. "Work hardening in micropillar compression: In situ experiments and modeling." Acta Materialia 59, no. 10 (2011): 3825–40. http://dx.doi.org/10.1016/j.actamat.2011.03.003.

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30

Yuan, Jianghuai, Shenghao Zhou, Haichen Wu, et al. "Ultrahigh strength-ductility of nanocrystalline Cr2AlC coating under micropillar compression." Scripta Materialia 235 (October 2023): 115594. http://dx.doi.org/10.1016/j.scriptamat.2023.115594.

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31

Thomas, Melonie P., Ryan Schoell, Nahid Sultan Al-Mamun, et al. "Real-Time Observation of Nanoscale Kink Band Mediated Plasticity in Ion-Irradiated Graphite: An In Situ TEM Study." Materials 17, no. 4 (2024): 895. http://dx.doi.org/10.3390/ma17040895.

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Graphite IG-110 is a synthetic polycrystalline material used as a neutron moderator in reactors. Graphite is inherently brittle and is known to exhibit a further increase in brittleness due to radiation damage at room temperature. To understand the irradiation effects on pre-existing defects and their overall influence on external load, micropillar compression tests were performed using in situ nanoindentation in the Transmission Electron Microscopy (TEM) for both pristine and ion-irradiated samples. While pristine specimens showed brittle and subsequent catastrophic failure, the 2.8 MeV Au2+
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32

Juri, Afifah Z., Animesh K. Basak, and Ling Yin. "In-situ SEM micropillar compression of porous and dense zirconia materials." Journal of the Mechanical Behavior of Biomedical Materials 132 (August 2022): 105268. http://dx.doi.org/10.1016/j.jmbbm.2022.105268.

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33

Östlund, Fredrik, Philip R. Howie, Rudy Ghisleni, et al. "Ductile–brittle transition in micropillar compression of GaAs at room temperature." Philosophical Magazine 91, no. 7-9 (2011): 1190–99. http://dx.doi.org/10.1080/14786435.2010.509286.

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34

Cornec, A., and E. Lilleodden. "Stress-strain curve estimation from micropillar compression with transverse contraction effect." Materials Today Communications 41 (December 2024): 110396. http://dx.doi.org/10.1016/j.mtcomm.2024.110396.

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35

Yilmaz, Ezgi D., Sabine Bechtle, Hüseyin Özcoban, Andreas Schreyer, and Gerold A. Schneider. "Fracture behavior of hydroxyapatite nanofibers in dental enamel under micropillar compression." Scripta Materialia 68, no. 6 (2013): 404–7. http://dx.doi.org/10.1016/j.scriptamat.2012.11.007.

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36

Wang, Peng, Fengxian Liu, Yinan Cui, Zhanli Liu, Shaoxing Qu, and Zhuo Zhuang. "Interpreting strain burst in micropillar compression through instability of loading system." International Journal of Plasticity 107 (August 2018): 150–63. http://dx.doi.org/10.1016/j.ijplas.2018.04.002.

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37

Thomas, K., G. Mohanty, J. Wehrs, et al. "Elevated and cryogenic temperature micropillar compression of magnesium–niobium multilayer films." Journal of Materials Science 54, no. 15 (2019): 10884–901. http://dx.doi.org/10.1007/s10853-019-03422-x.

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38

Williams, J. J., J. L. Walters, M. Y. Wang, N. Chawla, and A. Rohatgi. "Extracting Constitutive Stress–Strain Behavior of Microscopic Phases by Micropillar Compression." JOM 65, no. 2 (2012): 226–33. http://dx.doi.org/10.1007/s11837-012-0516-9.

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39

Lei, Qian, Jian Wang, and Amit Misra. "Mechanical Behavior of Al–Al2Cu–Si and Al–Al2Cu Eutectic Alloys." Crystals 11, no. 2 (2021): 194. http://dx.doi.org/10.3390/cryst11020194.

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In this study, laser rapid solidification technique was used to refine the microstructure of ternary Al–Cu–Si and binary Al–Cu eutectic alloys to nanoscales. Micropillar compression testing was performed to measure the stress–strain response of the samples with characteristic microstructure in the melt pool regions. The laser-remelted Al–Al2Cu–Si ternary alloy was observed to reach the compressive strength of 1.59 GPa before failure at a strain of 28.5%, which is significantly better than the as-cast alloy with a maximum strength of 0.48 GPa at a failure strain of 4.8%. The laser-remelted Al–C
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40

Inomoto, Masahiro, Norihiko L. Okamoto та Haruyuki Inui. "Compression of Single-Crystal Micropillars of the Γ Intermetallic Phase in the Fe-Zn System". Advanced Materials Research 922 (травень 2014): 264–69. http://dx.doi.org/10.4028/www.scientific.net/amr.922.264.

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The deformation behavior of the Γ (gamma) phase in the Fe-Zn system has been investigated via room-temperature compression tests of single-crystal micropillar specimens fabricated by the focused ion beam method. Trace analysis of slip lines indicates that {110} slip occurs for the specimens investigated in the present study. Although the slip direction has not been uniquely determined, the slip direction might be <111> in consideration of the crystal structure of the Γ phase (bcc).
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41

Tadano, Yuichi. "Numerical Study on Bicrystalline Micropillar Compression Using High-Order Gradient Crystal Plasticity." Key Engineering Materials 794 (February 2019): 65–70. http://dx.doi.org/10.4028/www.scientific.net/kem.794.65.

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Dislocation structures at crystalline scale play an important role in the scale effect of materials. The higher-order crystal plasticity, in which a dislocation information is introduced as the gradient of slip and affects the hardening behavior of slip, is a useful model to describe a scale dependency of metallic material. In this study, a large deformation finite element analysis of a bicrystalline micropillar is demonstrated to investigate the grain boundary effect on the dislocation motion. The effect of condition on the grain boundary is numerically discussed. It is suggested that the lar
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42

Chen, Zhenghao, and Haruyuki Inui. "Micropillar compression deformation of single crystals of Fe3Ge with the L12 structure." Acta Materialia 208 (April 2021): 116779. http://dx.doi.org/10.1016/j.actamat.2021.116779.

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43

Karakoc, Omer, Takaaki Koyanagi, Takashi Nozawa, and Yutai Katoh. "Fiber/matrix debonding evaluation of SiCf/SiC composites using micropillar compression technique." Composites Part B: Engineering 224 (November 2021): 109189. http://dx.doi.org/10.1016/j.compositesb.2021.109189.

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44

Wang, Jiangting, Chunhui Yang, and Peter D. Hodgson. "Strain gradients in Cu–Fe thin films and multilayers during micropillar compression." Materials Science and Engineering: A 651 (January 2016): 146–54. http://dx.doi.org/10.1016/j.msea.2015.10.105.

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45

DUBACH, A., R. RAGHAVAN, J. LOFFLER, J. MICHLER, and U. RAMAMURTY. "Micropillar compression studies on a bulk metallic glass in different structural states." Scripta Materialia 60, no. 7 (2009): 567–70. http://dx.doi.org/10.1016/j.scriptamat.2008.12.013.

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46

Wang, Jiangting, and Nicole Stanford. "A critical assessment of work hardening in TWIP steels through micropillar compression." Materials Science and Engineering: A 696 (June 2017): 42–51. http://dx.doi.org/10.1016/j.msea.2017.04.048.

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47

Wang, Qiang, Chris Cochrane, Fei Long, Hongbing Yu, and Mark R. Daymond. "Micropillar compression study on heavy ion irradiated Zr-2.5Nb pressure tube alloy." Journal of Nuclear Materials 511 (December 2018): 487–95. http://dx.doi.org/10.1016/j.jnucmat.2018.09.021.

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48

Kishida, Kyosuke, Yasuharu Shinkai, and Haruyuki Inui. "Room temperature deformation of 6H–SiC single crystals investigated by micropillar compression." Acta Materialia 187 (April 2020): 19–28. http://dx.doi.org/10.1016/j.actamat.2020.01.027.

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49

Hashizume, Yukichika, Masahiro Inomoto, Norihiko L. Okamoto, Hiroshi Takebayashi та Haruyuki Inui. "Micropillar compression deformation of single crystals of the intermetallic compound Γ-Fe4Zn9". Acta Materialia 199 (жовтень 2020): 514–22. http://dx.doi.org/10.1016/j.actamat.2020.08.062.

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50

Singh, Sudhanshu S., Enyu Guo, Huxiao Xie, and Nikhilesh Chawla. "Mechanical properties of intermetallic inclusions in Al 7075 alloys by micropillar compression." Intermetallics 62 (July 2015): 69–75. http://dx.doi.org/10.1016/j.intermet.2015.03.008.

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