Knowledge (XXG)

82:) is a process where a second phase that begins in solid solution with the matrix metal is precipitated out of solution with the metal as it is quenched, leaving particles of that phase distributed throughout to cause resistance to slip dislocations. This is achieved by first heating the metal to a temperature where the elements forming the particles are soluble then quenching it, trapping them in a solid solution. Had it been a liquid solution, the elements would form precipitates, just as supersaturated saltwater would precipitate small salt crystals, but atom diffusion in a solid is very slow at room temperature. A second heat treatment at a suitable temperature is then required to age the material. The elevated temperature allows the dissolved elements to diffuse much faster, and form the desired precipitated particles. The quenching is required since the material otherwise would start the precipitation already during the slow cooling. This type of precipitation results in few large particles rather than the, generally desired, profusion of small precipitates. Precipitation hardening is one of the most commonly used techniques for the hardening of metal alloys. 72:, a soluble alloying element is added to the material desired to be strengthened, and together they form a “solid solution”. A solid solution can be thought of just as a "normal" liquid solution, e.g. salt in water, except it is solid. Depending on the size of the dissolved alloying element's ion compared to that of the matrix-metal, it is dissolved either substitutionally (large alloying element substituting for an atom in the crystal) or interstitially (small alloying element taking a place between atoms in the crystal lattice). In both cases, the size difference of the foreign elements make them act as sand grains in sandpaper, resisting dislocations that try to slip by, resulting in higher material strength. In solution hardening, the alloying element does not precipitate from solution. 104:). In austenitic form, steel can dissolve a lot more carbon. Once the carbon has been dissolved, the material is then quenched. It is important to quench with a high cooling rate so that the carbon does not have time to form precipitates of carbides. When the temperature is low enough, the steel tries to return to the low temperature crystal structure BCC. This change is very quick since it does not rely on diffusion and is called a martensitic transformation. Because of the extreme supersaturation of solid solution carbon, the crystal lattice becomes BCT ( 385: 53: 65:. Ductile metal becomes harder and stronger as it's physically deformed. The plastic straining generates new dislocations. As the dislocation density increases, further dislocation movement becomes more difficult since they hinder each other, which means the material hardness increases. 54: 108:) instead. This phase is called martensite, and is extremely hard due to a combined effect of the distorted crystal structure and the extreme solid solution strengthening, both mechanisms of which resist slip dislocation. 96:, is a hardening mechanism specific for steel. The steel must be heated to a temperature where the iron phase changes from ferrite into austenite, i.e. changes crystal structure from BCC ( 227: 136: 733: 220: 695: 133: 124: 213: 37: 713: 754: 163: 723: 703: 495: 69: 656: 532: 85: 728: 580: 105: 671: 469: 718: 708: 595: 257: 75: 610: 527: 519: 485: 93: 352: 349: 681: 645: 600: 490: 464: 112: 650: 640: 636: 585: 575: 459: 438: 325: 292: 101: 97: 355: 252: 369: 61:(also referred to as strain hardening) the material is strained past its yield point, e.g. by 454: 433: 661: 414: 384: 318: 50: 130: 565: 547: 423: 419: 365: 183: 58: 748: 509: 298: 23: 623: 618: 345: 341: 155: 62: 34: 26: 666: 570: 427: 393: 555: 398: 308: 33: 676: 590: 361: 313: 270: 205: 89: 560: 302: 288: 280: 30: 240: 236: 209: 127: 120: 694: 609: 541: 518: 508: 478: 447: 407: 392: 334: 279: 266: 156:"Hall–Petch relation and boundary strengthening" 221: 184:"What is Work Hardening Steel? - Titus Steel" 8: 515: 404: 276: 228: 214: 206: 146: 7: 45:The five hardening processes are: 14: 383: 1: 253:History of ferrous metallurgy 154:Hansen, Niels (2 June 2004). 29:process used to increase the 496:Argon oxygen decarburization 70:solid solution strengthening 657:Differential heat treatment 771: 86:Martensitic transformation 632: 581:Ferritic nitrocarburizing 381: 248: 88:, more commonly known as 672:Post weld heat treatment 106:body-centered tetragonal 258:List of steel producers 76:Precipitation hardening 486:Electro-slag remelting 755:Metal heat treatments 696:Production by country 682:Superplastic forming 601:Quench polish quench 491:Vacuum arc remelting 470:Basic oxygen process 465:Electric arc furnace 16:Metalworking process 637:Cryogenic treatment 460:Open hearth furnace 448:Primary (Post-1850) 439:Cementation process 326:Direct reduced iron 102:face-centered cubic 98:body-centered cubic 408:Primary (Pre-1850) 742: 741: 690: 689: 504: 503: 379: 378: 370:Induction furnace 190:. 19 October 2023 762: 516: 455:Bessemer process 405: 387: 277: 230: 223: 216: 207: 200: 199: 197: 195: 180: 174: 173: 171: 169: 160: 151: 770: 769: 765: 764: 763: 761: 760: 759: 745: 744: 743: 738: 686: 662:Decarburization 628: 605: 546: 537: 500: 474: 443: 415:Pattern welding 396: 388: 375: 330: 319:Anthracite iron 268: 267:Iron production 262: 244: 234: 204: 203: 193: 191: 182: 181: 177: 167: 165: 158: 153: 152: 148: 143: 118: 43: 17: 12: 11: 5: 768: 766: 758: 757: 747: 746: 740: 739: 737: 736: 731: 726: 721: 716: 711: 706: 700: 698: 692: 691: 688: 687: 685: 684: 679: 674: 669: 664: 659: 654: 648: 643: 633: 630: 629: 627: 626: 621: 615: 613: 607: 606: 604: 603: 598: 593: 588: 583: 578: 573: 568: 566:Carbonitriding 563: 558: 552: 550: 548:Case-hardening 539: 538: 536: 535: 530: 524: 522: 513: 510:Heat treatment 506: 505: 502: 501: 499: 498: 493: 488: 482: 480: 476: 475: 473: 472: 467: 462: 457: 451: 449: 445: 444: 442: 441: 436: 434:Tatara furnace 431: 424:Damascus steel 420:Crucible steel 417: 411: 409: 402: 390: 389: 382: 380: 377: 376: 374: 373: 366:Cupola furnace 359: 338: 336: 332: 331: 329: 328: 323: 322: 321: 316: 311: 296: 285: 283: 274: 264: 263: 261: 260: 255: 249: 246: 245: 235: 233: 232: 225: 218: 210: 202: 201: 175: 145: 144: 142: 139: 138: 137: 134: 131: 128: 125: 117: 114: 110: 109: 83: 73: 66: 59:work hardening 55: 42: 39: 15: 13: 10: 9: 6: 4: 3: 2: 767: 756: 753: 752: 750: 735: 734:United States 732: 730: 727: 725: 722: 720: 717: 715: 712: 710: 707: 705: 702: 701: 699: 697: 693: 683: 680: 678: 675: 673: 670: 668: 665: 663: 660: 658: 655: 652: 649: 647: 644: 642: 638: 635: 634: 631: 625: 622: 620: 617: 616: 614: 612: 608: 602: 599: 597: 596:Precipitation 594: 592: 589: 587: 584: 582: 579: 577: 574: 572: 569: 567: 564: 562: 559: 557: 554: 553: 551: 549: 544: 540: 534: 533:Short circuit 531: 529: 526: 525: 523: 521: 517: 514: 511: 507: 497: 494: 492: 489: 487: 484: 483: 481: 477: 471: 468: 466: 463: 461: 458: 456: 453: 452: 450: 446: 440: 437: 435: 432: 429: 425: 421: 418: 416: 413: 412: 410: 406: 403: 400: 395: 391: 386: 371: 367: 363: 360: 357: 354: 351: 350:Reverberatory 347: 343: 340: 339: 337: 333: 327: 324: 320: 317: 315: 312: 310: 307: 306: 304: 300: 299:Blast furnace 297: 294: 290: 287: 286: 284: 282: 278: 275: 272: 265: 259: 256: 254: 251: 250: 247: 242: 238: 231: 226: 224: 219: 217: 212: 211: 208: 189: 185: 179: 176: 164: 157: 150: 147: 140: 135: 132: 129: 126: 123: 122: 121: 115: 113: 107: 103: 99: 95: 91: 87: 84: 81: 80:age hardening 78:(also called 77: 74: 71: 67: 64: 60: 56: 52: 48: 47: 46: 40: 38: 36: 32: 28: 25: 24:metallurgical 21: 624:Martempering 619:Austempering 542: 528:Low hydrogen 346:Finery forge 342:Wrought iron 192:. 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