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Journal articles on the topic 'Dynamic properties of materials'

Author: Grafiati
Published: 30 May 2022
Last updated: 31 May 2022

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1

Li, W. H., G. Chen, S. H. Yeo, and Hao Du. "Dynamic Properties of Magnetorheological Materials." Key Engineering Materials 227 (August 2002): 119–24. http://dx.doi.org/10.4028/www.scientific.net/kem.227.119.

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2

IISAKA, KATSUYOSHI. "Dynamic mechanical properties of composite materials." NIPPON GOMU KYOKAISHI 60, no. 3 (1987): 117–25. http://dx.doi.org/10.2324/gomu.60.117.

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3

Marlor, S. S., I. Miskioglu, and J. Ligon. "DYNAMIC MATERIAL PROPERTIES IN BIREFRINGENT MATERIALS." Experimental Techniques 18, no. 4 (July 1994): 39–42. http://dx.doi.org/10.1111/j.1747-1567.1994.tb00288.x.

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4

Cascone, Maria Grazia. "Dynamic-Mechanical Properties of Bioartificial Polymeric Materials." Polymer International 43, no. 1 (May 1997): 55–69. http://dx.doi.org/10.1002/(sici)1097-0126(199705)43:1<55::aid-pi762>3.0.co;2-#.

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5

Kulik, V. M., B. N. Semenov, and S. L. Morozova. "Measurement of dynamic properties of viscoelastic materials." Thermophysics and Aeromechanics 14, no. 2 (June 2007): 211–21. http://dx.doi.org/10.1134/s0869864307020072.

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6

Kulik, V. M., B. N. Semenov, A. V. Boiko, B. M. Seoudi, H. H. Chun, and I. Lee. "Measurement of Dynamic Properties of Viscoelastic Materials." Experimental Mechanics 49, no. 3 (August 2, 2008): 417–25. http://dx.doi.org/10.1007/s11340-008-9165-x.

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7

Ito, Hiroshi, and Hideo Komine. "Dynamic compaction properties of bentonite-based materials." Engineering Geology 98, no. 3-4 (May 2008): 133–43. http://dx.doi.org/10.1016/j.enggeo.2008.01.005.

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8

Ivanchuk, A. A., D. M. Karpinos, Yu V. Kondrat'ev, Yu I. Nezhentsev, A. E. Rutkovskii, V. Ya Bikernieks, O. O. Peterson, and V. A. Pekhovich. "Dynamic strength properties of permeable fibrous materials." Soviet Powder Metallurgy and Metal Ceramics 25, no. 6 (June 1986): 522–26. http://dx.doi.org/10.1007/bf00792395.

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9

Lurie, K. A. "MATERIAL OPTIMIZATION AND DYNAMIC MATERIALS." Cybernetics and Physics, Volume 10, 2021, Number 2 (October 1, 2021): 84–87. http://dx.doi.org/10.35470/2226-4116-2021-10-2-84-87.

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The paper is about the connection between material optimization in dynamics and a novel concept of dynamic materials (DM) defined as inseparable union of a framework and the fluxes of mass, momentum, and energy existing in time dependent material formations. An example of a spatial-temporal material geometry is discussed as illustration of a DM capable of accumulating wave energy. Finding the optimal material layouts in dynamics demonstrates conceptual difference from a similar procedure in statics. In the first case, the original constituents are distributed in space-time, whereas in the second - in space alone. The habitual understanding of a material as an isolated framework has come from statics, but a transition to dynamics brings in a new component - the fluxes of mass, momentum, and energy. Based on Noether theorem, these fluxes connect the framework with the environment into inseparable entity termed dynamic material (DM). The key role of DM is that they support controls that may purposefully change the material properties in both space and time, which is the main goal of optimization.
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10

He, W., T. Xing, G. X. Liao, W. Lin, F. Deng, and X. G. Jian. "Dynamic Mechanical Properties of PPESK/Silica Hybrid Materials." Polymer-Plastics Technology and Engineering 48, no. 2 (February 2, 2009): 164–69. http://dx.doi.org/10.1080/03602550802577379.

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11

Hosono, Nobuhiko. "Design of Porous Coordination Materials with Dynamic Properties." Bulletin of the Chemical Society of Japan 94, no. 1 (January 15, 2021): 60–69. http://dx.doi.org/10.1246/bcsj.20200242.

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12

Acher, O., and A. L. Adenot. "Bounds on the dynamic properties of magnetic materials." Physical Review B 62, no. 17 (November 1, 2000): 11324–27. http://dx.doi.org/10.1103/physrevb.62.11324.

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13

Chen, Jiang-ying, Cheng-cheng Liu, Hai-wei Dong, De-sheng Shi, Zhong-xiao Zhang, and Dong-jie Wang. "Dynamic properties of concrete materials under shock loading." Construction and Building Materials 39 (February 2013): 119–23. http://dx.doi.org/10.1016/j.conbuildmat.2012.05.011.

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14

Adams, R. D., and M. R. Maheri. "The dynamic shear properties of structural honeycomb materials." Composites Science and Technology 47, no. 1 (January 1993): 15–23. http://dx.doi.org/10.1016/0266-3538(93)90091-t.

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15

Mozur, Eve M., and James R. Neilson. "Cation Dynamics in Hybrid Halide Perovskites." Annual Review of Materials Research 51, no. 1 (July 26, 2021): 269–91. http://dx.doi.org/10.1146/annurev-matsci-080819-012808.

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Hybrid halide perovskite semiconductors exhibit complex, dynamical disorder while also harboring properties ideal for optoelectronic applications that include photovoltaics. However, these materials are structurally and compositionally distinct from traditional compound semiconductors composed of tetrahedrally coordinated elements with an average valence electron count of silicon. The additional dynamic degrees of freedom of hybrid halide perovskites underlie many of their potentially transformative physical properties. Neutron scattering and spectroscopy studies of the atomic dynamics of these materials have yielded significant insights into their functional properties. Specifically, inelastic neutron scattering has been used to elucidate the phonon band structure, and quasi-elastic neutron scattering has revealed the nature of the uncorrelated dynamics pertaining to molecular reorientations. Understanding the dynamics of these complex semiconductors has elucidated the temperature-dependent phase stability and origins of defect-tolerant electronic transport from the highly polarizable dielectric response. Furthermore, the dynamic degrees of freedom of the hybrid perovskites provide additional opportunities for application engineering and innovation.
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16

Rambaut, C., H. Jobic, H. Jaffrezic, J. Kohanoff, and S. Fayeulle. "Molecular dynamics simulation of the lattice: dynamic properties." Journal of Physics: Condensed Matter 10, no. 19 (May 18, 1998): 4221–29. http://dx.doi.org/10.1088/0953-8984/10/19/010.

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17

Yao, Zi-Shuo, Zheng Tang, and Jun Tao. "Bistable molecular materials with dynamic structures." Chemical Communications 56, no. 14 (2020): 2071–86. http://dx.doi.org/10.1039/c9cc09238b.

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18

Benmammar, Mohammed, and Hacene Sidi Mohammed El Amine Boukli. "Influence of silica fume on the dynamic properties of concrete." Journal of Building Materials and Structures 5, no. 1 (June 4, 2018): 102–9. http://dx.doi.org/10.34118/jbms.v5i1.49.

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Ultrasonic pulse velocity and resonance frequency methods are non-destructive tests that allow the evaluation and control of building materials. They have been used to determine the dynamic properties of concrete, which are used in the design and control of structures and which are the key elements of the dynamics of materials. In this study, we chose a non-destructive approach to quantify -in laboratory- the influence of adding silica fume on ordinary concrete’s dynamic characteristics. However, several concrete mixtures have been prepared with limestone aggregates. The experimental plan used, allowed us to determine the dynamic elasticity modulus and the dynamic rigidity modulus of different formulated concretes.
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19

Cordill, M. J., N. R. Moody, and W. W. Gerberich. "Effects of dynamic indentation on the mechanical response of materials." Journal of Materials Research 23, no. 6 (June 2008): 1604–13. http://dx.doi.org/10.1557/jmr.2008.0205.

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Dynamic indentation techniques are often used to determine mechanical properties as a function of depth by continuously measuring the stiffness of a material. The dynamics are used by superimposing an oscillation on top of the monotonic loading. Of interest was how the oscillation affects the measured mechanical properties when compared to a quasi-static indent run at the same loading conditions as a dynamic. Single crystals of nickel and NaCl as well as a polycrystalline nickel sample and amorphous fused quartz and polycarbonate have all been studied. With respect to dynamic oscillations, the result is a decrease of the load at the same displacement and thus lower measured hardness values of the ductile crystalline materials. It has also been found that the first 100 nm of displacement are the most affected by the oscillating tip, an important length scale for testing thin films, nanopillars, and nanoparticles.
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20

Sun, Ya Zhou, Yong Heng Li, Hai Tao Liu, and Zong Shan Liu. "Experimental Study of Dynamic Properties of Mechanical Joint Surfaces." Advanced Materials Research 694-697 (May 2013): 181–85. http://dx.doi.org/10.4028/www.scientific.net/amr.694-697.181.

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Dynamic properties of mechanical joint surfaces are researched, majorly contains the study of basic mechanism and factors affect the dynamic properties of joint surfaces. Equivalent stiffness and damp are analyzed. Orthogonal experiments are arranged in order to analyze the weight of every major factor that affects the joint surfaces dynamics. Two common materials HT200, 2Cr13 under different processing methods, surface roughness and surface areas are used.
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21

SANTAWISUK, Wallapat, Widchaya KANCHANAVASITA, Chakrit SIRISINHA, and Choltacha HARNIRATTISAI. "Dynamic viscoelastic properties of experimental silicone soft lining materials." Dental Materials Journal 29, no. 4 (2010): 454–60. http://dx.doi.org/10.4012/dmj.2009-126.

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22

NIKKESHI, Susumu, Kiyoshi SUZUKI, Masuo KUDO, and Toru MASUKO. "Dynamic Viscoelastic Properties of Zeolite/Polycarbonate Resin Composite Materials." Seikei-Kakou 8, no. 11 (1996): 751–56. http://dx.doi.org/10.4325/seikeikakou.8.751.

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23

Rajendran, R., Vijay Petley, and Birgit Rehmer. "Dynamic elastic properties of aero-engine metallic isotropic materials." Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications 227, no. 3 (July 17, 2012): 243–49. http://dx.doi.org/10.1177/1464420712454071.

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24

SHIGETO, N., Y. YAMADA, H. IWANAGA, A. SUBIANTO, and T. HAMADA. "Setting properties of alginate impression materials in dynamic viscoelasticity." Journal of Oral Rehabilitation 24, no. 10 (October 1997): 761–65. http://dx.doi.org/10.1046/j.1365-2842.1997.00563.x.

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25

SHIGETO, N., Y. YAMADA, H. IWANAGA, A. SUBIANTO, and T. HAMADA. "Setting properties of alginate impression materials in dynamic viscoelasticity." Journal of Oral Rehabilitation 24, no. 10 (June 28, 2008): 761–65. http://dx.doi.org/10.1111/j.1365-2842.1997.tb00273.x.

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26

Mancusi, Geminiano, Francesco Fabbrocino, Luciano Feo, and Fernando Fraternali. "Size effect and dynamic properties of 2D lattice materials." Composites Part B: Engineering 112 (March 2017): 235–42. http://dx.doi.org/10.1016/j.compositesb.2016.12.026.

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27

Kunin, Valentin, Shu Yang, Yigil Cho, Pierre Deymier, and David J. Srolovitz. "Static and dynamic elastic properties of fractal-cut materials." Extreme Mechanics Letters 6 (March 2016): 103–14. http://dx.doi.org/10.1016/j.eml.2015.12.003.

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28

Fang, X. Q., C. Hu, and W. H. Huang. "Determination of dynamic effective properties in functionally graded materials." Acta Mechanica 192, no. 1-4 (February 21, 2007): 49–63. http://dx.doi.org/10.1007/s00707-006-0440-6.

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29

GAMOTA, DANIEL R., and FRANK E. FILISKO. "LINEAR/NONLINEAR MECHANICAL PROPERTIES OF ELECTRORHEOLOGICAL MATERIALS." International Journal of Modern Physics B 06, no. 15n16 (August 1992): 2595–607. http://dx.doi.org/10.1142/s0217979292001316.

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The stress response of an electrorheological (ER) material is modified by the application of an electric field. Various studies have shown that the ER material can behave as a linear viscous, linear viscoelastic, nonlinear viscoelastic, plastic, or viscoelastic-plastic body. Furthermore, several different experimental techniques are conducted to observe the ER material's behavior as a function of strain, strain frequency, field strength, and ER material concentration. Small amplitude dynamic studies are used to observe the ER material's linear viscoelastic properties, while moderate and large amplitude studies are used to observe the material's fundamental nonlinear dynamic properties. Finally, constant shear rate experiments are performed to observe the apparent viscosity of the ER material during flow conditions.
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30

Liu, Fang, Guang Meng, and Mei Zhao. "Viscoelastic Influence on Dynamic Properties of PCB Under Drop Impact." Journal of Electronic Packaging 129, no. 3 (March 15, 2007): 266–72. http://dx.doi.org/10.1115/1.2753910.

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Dynamic properties of printed circuit board (PCB) assembly under drop impact are investigated when viscoelasticity of substrate materials is considered. The main materials of a PCB substrate are macromolecule resins, which are typical viscoelastic materials. From the viewpoint of viscoelasticity, the dynamics of PCBs under drop impact is analyzed based on mass-damping-spring, beam, and plate theories. It is demonstrated that the viscoelasticity of a PCB has distinct influences on the dynamic properties of PCBs under board-level drop impact. When there is an increase in the viscosity of substrate materials, the damping coefficients of PCBs would rise, its deflection and acceleration responses could diminish faster, and the maximum deflection of PCBs would become smaller. Meanwhile, with the same viscosity and drop impact conditions, a larger plate would produce a bigger deflection response. Therefore, drop impact reliability could be enhanced by choosing substrate material of larger viscoelasticity and reducing properly the size of PCBs. Dynamic analysis of PCBs under drop impact not only contributes to perfecting theoretical research, but also provides a reference for the choice of substrate materials and reliability design of PCBs when electronic products are devised.
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31

Marcos, A., A. Rodríguez, and L. González. "Dynamic properties of copolyetherureas." Journal of Non-Crystalline Solids 172-174 (September 1994): 1125–29. http://dx.doi.org/10.1016/0022-3093(94)90633-5.

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32

TAKAHARA, ATSUSHI. "Dynamic Viscoelastic Properties." FIBER 65, no. 12 (2009): P.472—P.476. http://dx.doi.org/10.2115/fiber.65.p_472.

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33

Naboka, V. I., G. A. Polyanskii, A. P. Fomenko, and N. V. Krutas. "Dynamic properties of blast furnaces." Steel in Translation 38, no. 10 (October 2008): 833–36. http://dx.doi.org/10.3103/s0967091208100100.

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34

Wolfenden, A., J. Sousa, and CL Monismith. "Dynamic Properties of Asphalt Concrete." Journal of Testing and Evaluation 16, no. 4 (1988): 350. http://dx.doi.org/10.1520/jte11078j.

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35

Vakil, Jafer R., Nethmi De Alwis Watuthanthrige, Zachary A. Digby, Borui Zhang, Hannah A. Lacy, Jessica L. Sparks, and Dominik Konkolewicz. "Controlling polymer architecture to design dynamic network materials with multiple dynamic linkers." Molecular Systems Design & Engineering 5, no. 7 (2020): 1267–76. http://dx.doi.org/10.1039/d0me00015a.

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A series of network materials containing dynamic hydrogen bonded and dynamic covalent Diels–Alder units are developed, with a focus on engineering the materials mechanical and self healing properties by tuning the underlying polymer's structure.
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36

Stopler, Erika B., Obed J. Dodo, Alexander C. Hull, Kyle A. Weaver, Progyateg Chakma, Richard Edelmann, Logan Ranly, Mehdi B. Zanjani, Zhijiang Ye, and Dominik Konkolewicz. "Carbon nanotube enhanced dynamic polymeric materials through macromolecular engineering." Materials Advances 1, no. 5 (2020): 1071–76. http://dx.doi.org/10.1039/d0ma00143k.

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Diels–Alder based dynamic polymer materials are reinforced with carbon nanotubes, to give materials with self-healing properties from the dynamic matrix and with enhanced mechanical and electrical properties from the carbon nanotubes.
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37

Hamakawa, S., M. Aniya, and F. Shimojo. "Dynamic properties of AgI1−xClx: A molecular dynamics study." Solid State Ionics 176, no. 31-34 (October 2005): 2471–75. http://dx.doi.org/10.1016/j.ssi.2005.05.021.

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38

Aoki, Keiko M. "Dynamics and Elastic Properties of Glassy Metastable States." Solids 2, no. 2 (June 4, 2021): 249–64. http://dx.doi.org/10.3390/solids2020016.

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By a molecular dynamics (MD) simulation method which ensures the system will be under hydrostatic pressure, dynamic and elastic properties of glassy metatstable states are investigated. In the MD method, the simulation cell fluctuates not only in volume but also in shape under constant hydrostatic pressure and temperature. As observed in experiments for many glass forming materials, metastable states in our simulation show a sharp increase in mean-square-displacement at certain temperatures TD. Dynamic heterogeneity is also observed at TD. Elastic properties are calculated from stress and strain relations obtained from the spontaneous fluctuation of internal stress tensor and simulation cell parameters. Each investigated state shows distinctive dynamics while maintaining solid-like elastic properties. The elastic properties stay intact even above TD. It has been shown that the rigidity and mobility of glassy metastable states are compatible under dynamic heterogeneity.
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39

Stupakov, A., and A. Perevertov. "Dynamic properties of micro-magnetic noise in soft ferromagnetic materials." Journal of Magnetism and Magnetic Materials 456 (June 2018): 390–99. http://dx.doi.org/10.1016/j.jmmm.2018.02.069.

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40

王, 硕. "Energy-Based Mechanical Properties Analysis of Materials under Dynamic Loading." International Journal of Mechanics Research 09, no. 01 (2020): 18–23. http://dx.doi.org/10.12677/ijm.2020.91003.

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41

Thompson, David E. "Dynamic Properties of Soft Tissues and Their Interface with Materials." Journal of Hand Therapy 8, no. 2 (April 1995): 85–90. http://dx.doi.org/10.1016/s0894-1130(12)80304-8.

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42

ABE, Y., T. TAJI, K. HIASA, K. TSUGA, and Y. AKAGAWA. "Dynamic viscoelastic properties of vinyl polysiloxane denture soft lining materials." Journal of Oral Rehabilitation 36, no. 12 (December 2009): 887–93. http://dx.doi.org/10.1111/j.1365-2842.2009.02015.x.

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43

Lovesey, Stephen W., and Colin G. Windsor. "Studies of the Dynamic Properties of Materials Using Neutron Scattering." Annual Review of Materials Science 16, no. 1 (August 1986): 87–112. http://dx.doi.org/10.1146/annurev.ms.16.080186.000511.

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44

Zhao, Jun Liang, Li Xin Li, and Zhong Juan Yang. "Dynamic Mechanical Properties of a Novel Structural Radar Absorbing Materials." Applied Mechanics and Materials 364 (August 2013): 771–74. http://dx.doi.org/10.4028/www.scientific.net/amm.364.771.

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A novel structural radar absorbing materials (SRAM), which give the new absorbing microwaves function to the normal resin-base composites, were prepared. The dynamic compressive tests of SRAM were carried out along both in-plane and normal plane directions of composites by means of the Split Hopkinson Pressure Bar (SHPB). In compressive test along in-plane direction, failure happened at the interface between fiber and matrix. Fracture mode and mechanism was proposed to explain these results. The adding of magnetic absorbing particles resulted in the deterioration of the compressive properties. But there was no obvious decrease on compressive strength of SRAM with the radar absorbing properties.
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45

Rajpal, Rohit, K. P. Lijesh, Mohit Kant, and K. V. Gangadharan. "Experimental study on the dynamic properties of magneto-rheological materials." IOP Conference Series: Materials Science and Engineering 402 (September 20, 2018): 012140. http://dx.doi.org/10.1088/1757-899x/402/1/012140.

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46

Popov, N. N. "Mechanical properties of structural materials under static and dynamic loads." Metal Science and Heat Treatment 29, no. 4 (April 1987): 251–54. http://dx.doi.org/10.1007/bf00769421.

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47

Abhishek, M. R., P. M. Suresh, N. Ranganath, and D. P. Girish. "An investigation on dynamic mechanical properties of hybrid composite materials." Materials Today: Proceedings 46 (2021): 9111–13. http://dx.doi.org/10.1016/j.matpr.2021.05.400.

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48

Fox, C., S. Kishore, K. Senol, and A. Shukla. "Experiments in measuring dynamic hydrostatic constitutive properties of soft materials." Mechanics of Materials 160 (September 2021): 103948. http://dx.doi.org/10.1016/j.mechmat.2021.103948.

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49

Nizhegorodov, V. V. "Dynamic viscoelastic properties of polymeric constructional materials based on polycarbonate." Izvestiya MGTU MAMI 1, no. 2 (January 20, 2007): 192–95. http://dx.doi.org/10.17816/2074-0530-69707.

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The paper presents the research of viscoelastic properties of polymeric constructional materials based on polycarbonate using the methods of acoustic spectroscopy. The research was conducted using the method of free torsional vibrations at the low-frequency acoustic spectrometry, performed on the basis of inverse torsion pendulum. In the measurement process the dynamic shear modulus G 'and mechanical loss-angle tangent tgδ have been obtained. Measurements were performed in a wide temperature range from -180 to 200 ° C. It was shown that the reduction of impact strength at low temperature area is connected with the difference in chemical structure and the introduction of impact modifier.
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50

Singh, Alok, and James E. Saal. "Dynamic Properties of Magnesium Alloys." JOM 66, no. 2 (January 1, 2014): 275–76. http://dx.doi.org/10.1007/s11837-013-0844-4.

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