Size, Temperature, and Strain-Rate Dependence on  Tensile Mechanical Behaviors of Ni<sub><b>3</b></sub>Sn<sub><b>4</b></sub> Intermetallic Compound Using Molecular Dynamics Simulation

<table>(a) The tensile <svg height="9.71411pt" id="M106" style="vertical-align:-3.31357pt" version="1.1" viewbox="-0.0498162 -6.40054 36.7877 9.71411" width="36.7877pt" xmlns="http://www.w3.org/2000/svg" xmlns:xlink="http://www.w3.org/1999/xlink"><g transform="matrix(.0135,0,0,-0.0135,0,0)"><path d="M548 455L523 469C505 448 490 439 461 439C416 439 374 447 316 447C144 447 23 310 23 161C23 47 89 -12 179 -12C312 -12 429 106 429 244C429 303 419 344 368 386L371 388C404 383 440 378 474 378C507 378 530 411 548 455ZM350 274C350 191 308 25 198 25C144 25 108 75 108 157C108 264 170 395 276 395C296 395 320 384 333 360C347 334 350 316 350 274Z" id="g113-240"></path><glyph.data ascent="3473" descent="-2876" horiz-adv-x="565" vert-adv-y="565"></glyph.data></g><g transform="matrix(.0095,0,0,-0.0095,7.045,3.264)"><path d="M389 0V32C297 38 291 46 291 118V635C234 613 175 595 109 583V556L161 554C203 552 207 547 207 497V118C207 46 201 38 110 32V0H389Z" id="g50-50"></path><glyph.data ascent="3443" 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transform="matrix(.0135,0,0,-0.0135,41.174,0)"><path d="M241 635C89 635 35 457 35 312C35 153 89 -12 240 -12C390 -12 443 166 443 312C443 466 390 635 241 635ZM238 602C329 602 354 454 354 312C354 172 330 22 240 22C152 22 124 173 124 313S148 602 238 602Z" id="g113-49"></path><glyph.data ascent="3473" descent="-2876" horiz-adv-x="480" vert-adv-y="480"></glyph.data></g><g transform="matrix(.0135,0,0,-0.0135,47.677,0)"><path d="M241 635C89 635 35 457 35 312C35 153 89 -12 240 -12C390 -12 443 166 443 312C443 466 390 635 241 635ZM238 602C329 602 354 454 354 312C354 172 330 22 240 22C152 22 124 173 124 313S148 602 238 602Z" id="g113-49"></path><glyph.data ascent="3473" descent="-2876" horiz-adv-x="480" vert-adv-y="480"></glyph.data></g></svg>” Ni<sub>3</sub>Sn<sub>4</sub> nanowire model at 300 K and strain rate = 10<sup>−4</sup>% ps<sup>−1</sup>, (b) snapshots of fracture evolution of the Ni<sub>3</sub>Sn<sub>4</sub> atomic structure at various strains, and (c) the residual strain after unloading versus the applied strain.</table>

Journal of Nanomaterials

fig9

Figure 9

Figure 9: Size, Temperature, and Strain-Rate Dependence on  Tensile Mechanical Behaviors of Ni<sub><b>3</b></sub>Sn<sub><b>4</b></sub> Intermetallic Compound Using Molecular Dynamics Simulation 

Figure 9 | Size, Temperature, and Strain-Rate Dependence on  Tensile Mechanical Behaviors of Ni3Sn4 Intermetallic Compound Using Molecular Dynamics Simulation 