Transgranular fracture explained

Transgranular fracture is a type of fracture that occurs through the crystal grains of a material. In contrast to intergranular fractures, which occur when a fracture follows the grain boundaries, this type of fracture traverses the material's microstructure directly through individual grains. This type of fracture typically results from a combination of high stresses and material defects, such as voids or inclusions, that create a path for crack propagation through the grains. A broad range of ductile or brittle materials, including metals, ceramics, and polymers, can experience transgranular fracture. When examined under scanning electron microscopy, this type of fracture reveals cleavage steps, river patterns, feather markings, dimples, and tongues.[1] The fracture may change directions somewhat when entering a new grain in order to follow the new lattice orientation of that grain but this is a less severe direction change then would be required to follow the grain boundary. This results in a fairly smooth looking fracture with fewer sharp edges than one that follows the grain boundaries.[2] This can be visualized as a jigsaw puzzle cut from a single sheet of wood with the wood grain showing. A transgranular fracture follows the grains in the wood, not the jigsaw edges of the puzzle pieces. This is in contrast to an intergranular fracture which, in this analogy, would follow the jigsaw edges, not the wood grain.

Mechanism of transgranular fracture

The mechanism of transgranular fracture may vary depending on the material and surrounding conditions under which the fracture occurs.[3] However, some general steps are typically involved in the transgranular fracture process:

In ductile metals, the plastic deformation of the material can be a critical factor in the transgranular fracture process, while in brittle materials such as ceramics, the formation and growth of cracks can be influenced by factors such as grain size, porosity, and the presence of impurities or other defects.

Factors affecting transgranular fracture

Transition from intergranular to transgranular fracture

The fracture behavior of materials can be significantly changed by the use of precipitation-based grain boundary design. For example, Meindlhumer et. al.[9] produced a thin film of AlCrN containing a specific distribution of precipitates within the grain boundaries in precipitation-based grain boundary design. The precipitates acted as a barrier to crack propagation, increasing the material's resistance to intergranular cracking. Additionally, the precipitates altered the stress distribution within the material, promoting transgranular crack propagation instead. Furthermore, smaller precipitates with a more uniform distribution have been shown to be more effective at promoting transgranular fracture.

Notes and References

  1. Web site: Parks . Brian . 2012-03-16 . Tubular fracturing: Pinpointing the cause . Drilling Contractor . 2023-05-11.
  2. Web site: Types of Brittle Fracture . dead . https://web.archive.org/web/20160130020054/http://www.sv.vt.edu/classes/MSE2094_NoteBook/97ClassProj/exper/ballard/www/ballard.html . 2016-01-30.
  3. Book: Courtney, Thomas H. . Mechanical Behavior of Materials . Waveland Press . 2005 . 1577664256 . 2nd.
  4. Syu . D. -G. C. . Ghosh . A. K. . 1994-07-15 . The effect of temperature on the fracture mechanism in 2014A1/15vol.%Al2O3 composite . Materials Science and Engineering: A . 184 . 1 . 27–35 . 0921-5093 . 2027.42/31436 . free . 10.1016/0921-5093(94)91071-5 .
  5. Charitidis . C A . Karakasidis . T E . Kavouras . P . Karakostas . Th . 2007-07-04 . The size effect of crystalline inclusions on the fracture modes in glass–ceramic materials . Journal of Physics: Condensed Matter . 19 . 26 . 266209 . 0953-8984 . 10.1088/0953-8984/19/26/266209 . 21694086 .
  6. Robertson . I. M. . Tabata . T. . Wei . W. . Heubaum . F. . Birnbaum . H. K. . 1984-08-01 . Hydrogen embrittlement and grain boundary fracture . Scripta Metallurgica . 18 . 8 . 841–846 . 0036-9748 . 10.1016/0036-9748(84)90407-1 .
  7. Singh . Dileep . Shetty . Dinesh K. . January 1989 . Fracture Toughness of Polycrystalline Ceramics in Combined Mode I and Mode II Loading . Journal of the American Ceramic Society . 72 . 1 . 78–84 . 0002-7820 . 10.1111/j.1151-2916.1989.tb05957.x .
  8. Pedersen . Ketill O. . Børvik . Tore . Hopperstad . Odd Sture . 2011-01-01 . Fracture mechanisms of aluminium alloy AA7075-T651 under various loading conditions . Materials & Design . 32 . 1 . 97–107 . 0261-3069 . 10.1016/j.matdes.2010.06.029 .
  9. Meindlhumer . M. . Ziegelwanger . T. . Zalesak . J. . Hans . M. . Löfler . L. . Spor . S. . Jäger . N. . Stark . A. . Hruby . H. . Daniel . R. . Holec . D. . Schneider . J. M. . Mitterer . C. . Keckes . J. . 2022-09-15 . Precipitation-based grain boundary design alters Inter- to Trans-granular Fracture in AlCrN Thin Films . Acta Materialia . 237 . 118156 . 1359-6454 . 10.1016/j.actamat.2022.118156 .