Advanced search
Publication Cover
Philosophical Magazine B Volume 77, 1998 - Issue 3
Journal homepage
69
Views
35
CrossRef citations to date
0
Altmetric
Original Articles

Chemical embrittlement of Fe grain boundaries: P and the P-Mo couple

L. P. Sagert Department of Materials Science and Engineering, Northwestern University, Evanston, Illinois, 60208, USA
,
G. B. Olson Department of Materials Science and Engineering, Northwestern University, Evanston, Illinois, 60208, USA
&
D. E. Ellis Department of Physics and Astronomy and Materials, Research Center Northwestern University, Evanston, Illinois, 60208, USA
Pages 871-889 | Received 18 Jul 1997, Accepted 11 Aug 1997, Published online: 13 Aug 2009

Citations (35)

Keep up to date with the latest research on this topic with citation updates for this article.

Subscribe to citation updates

Read on this site (3)

S. von Willingh & R.D. Knutsen. (2022) Effect of prior austenitisation temperature on creep rupture in Grade 22 steel. Materials at High Temperatures 39:6, pages 507-515.
Read now
D.A. Mirzaev, A.A. Mirzoev, K.Yu. Okishev & A.V. Verkhovykh. (2016) Ab initio modelling of the interaction of H interstitials with grain boundaries in bcc Fe. Molecular Physics 114:9, pages 1502-1512.
Read now
A. V. Barashev . (2005) Monte Carlo simulation of phosphorus diffusion in α-iron via the vacancy mechanism. Philosophical Magazine 85:14, pages 1539-1555.
Read now

Articles from other publishers (32)

Mengmeng Yang, Jiaying Zhou, Haijun Huang, Shuo Cao, Qing-Miao Hu, Wei Li, Qingjun Chen, Yanxin Qiao & Hao Wang. (2023) High-throughput first-principles investigation on grain boundary segregation of alloying elements in ferritic steel. Journal of Materials Research and Technology 26, pages 2140-2150.
Crossref
Han Lin Mai, Xiang-Yuan Cui, Daniel Scheiber, Lorenz Romaner & Simon P. Ringer. (2023) Phosphorus and transition metal co-segregation in ferritic iron grain boundaries and its effects on cohesion. Acta Materialia 250, pages 118850.
Crossref
Y.C. Jiang, J. Zhao, L. Sun, H.R. Gong & X. Gong. (2022) Effects of alloying elements on cohesion and brittleness of grain boundary of iron. Materials Chemistry and Physics 275, pages 125291.
Crossref
Elin Toijer, Pär A.T. Olsson & Pär Olsson. (2021) Ab initio modelling of intergranular fracture of nickel containing phosphorus: Interfacial excess properties. Nuclear Materials and Energy 28, pages 101055.
Crossref
D. Scheiber, K. Prabitz, L. Romaner & W. Ecker. (2020) The influence of alloying on Zn liquid metal embrittlement in steels. Acta Materialia 195, pages 750-760.
Crossref
S.S. Kulkov, A.V. Bakulin & S.E. Kulkova. (2018) Effect of boron on the hydrogen-induced grain boundary embrittlement in α-Fe. International Journal of Hydrogen Energy 43:3, pages 1909-1925.
Crossref
Pavel Lejček, Mojmír Šob & Václav Paidar. (2017) Interfacial segregation and grain boundary embrittlement: An overview and critical assessment of experimental data and calculated results. Progress in Materials Science 87, pages 83-139.
Crossref
Pavel Lejček, Pavel Šandera, Jana Horníková, Petr Řehák & Jaroslav Pokluda. (2017) Grain boundary segregation of elements of groups 14 and 15 and its consequences for intergranular cohesion of ferritic iron. Journal of Materials Science 52:10, pages 5822-5834.
Crossref
Masanari Tomozawa, Yuichi Miyahara & Kenji Kako. (2013) Solute segregation on Σ3 and random grain boundaries in type 316L stainless steel. Materials Science and Engineering: A 578, pages 167-173.
Crossref
T. Nakazawa, T. Igarashi, T. Tsuru, Y. Kaji & S. Jitsukawa. (2011) Density functional calculations for small iron clusters with substitutional phosphorus. Journal of Nuclear Materials 417:1-3, pages 1090-1093.
Crossref
E Wachowicz & A Kiejna. (2011) Effect of impurities on structural, cohesive and magnetic properties of grain boundaries in α-Fe. Modelling and Simulation in Materials Science and Engineering 19:2, pages 025001.
Crossref
E. Wachowicz, T. Ossowski & A. Kiejna. (2010) Cohesive and magnetic properties of grain boundaries in bcc Fe with Cr additions. Physical Review B 81:9.
Crossref
Jia-Xiang Shang, Xiao-Dan Zhao, Fu-He Wang, Chong-Yu Wang & Hui-Bin Xu. (2006) Effects of Co and Cr on bcc Fe grain boundaries cohesion from first-principles study. Computational Materials Science 38:1, pages 217-222.
Crossref
Christophe Domain. (2006) Ab initio modelling of defect properties with substitutional and interstitials elements in steels and Zr alloys. Journal of Nuclear Materials 351:1-3, pages 1-19.
Crossref
C. Domain & C. S. Becquart. (2005) Diffusion of phosphorus in : An ab initio study . Physical Review B 71:21.
Crossref
Hiroshi YAGUCHIShogo MURAKAMINobuyuki FUJITSUNATomohiko SHINYAMasato YAMADATadamichi SAKAI. (2005) Long-term Isothermal Aging Behaviors of V Modified 2.25Cr-1 Mo Steels. Tetsu-to-Hagane 91:12, pages 888-896.
Crossref
Shan-Ying Wang, Chong-Yu Wang & Dong-Liang Zhao. (2004) Effect of double boron impurities on the α-iron grain boundary cohesion. Journal of Alloys and Compounds 368:1-2, pages 308-311.
Crossref
R Yang, R Z Huang, Y M Wang, H Q Ye & C Y Wang. (2003) The effects of 3d alloying elements on grain boundary cohesion in  -iron: a first principles study on interface embrittlement due to the segregation. Journal of Physics: Condensed Matter 15:49, pages 8339-8349.
Crossref
H.K.D.H. Bhadeshia. 2003. Comprehensive Structural Integrity. Comprehensive Structural Integrity 2 25 .
H.K.D.H. Bhadeshia. 2003. Comprehensive Structural Integrity. Comprehensive Structural Integrity 1 23 .
A.J. Freeman. (2002) Materials by design and the exciting role of quantum computation/simulation. Journal of Computational and Applied Mathematics 149:1, pages 27-56.
Crossref
Jia-Xiang Shang & Chong-Yu Wang. (2002) First-principles investigation of brittle cleavage fracture of Fe grain boundaries. Physical Review B 66:18.
Crossref
R. Yang, Y. M. Wang, R. Z. Huang, H. Q. Ye & C. Y. Wang. (2002) First-principles study on the effect of Mn and N on the cohesion of a γ-iron grain boundary. Physical Review B 65:9.
Crossref
Jia-Xiang Shang, Chong-Yu Wang & Dong-Liang Zhao. (2001) First-principles investigation of the effect of alloying elements Ti, V on grain boundary cohesion of FCC Fe. Computational Materials Science 22:3-4, pages 193-199.
Crossref
W.T. Geng, A.J. Freeman & G.B. Olson. (2001) Influence of alloying additions on the impurity induced grain boundary embrittlement. Solid State Communications 119:10-11, pages 585-590.
Crossref
W. T. Geng, A. J. Freeman & G. B. Olson. (2001) Influence of alloying additions on grain boundary cohesion of transition metals: First-principles determination and its phenomenological extension. Physical Review B 63:16.
Crossref
R. Yang, D.L. Zhao, Y.M. Wang, S.Q. Wang, H.Q. Ye & C.Y. Wang. (2001) Effects of Cr, Mn on the cohesion of the γ-iron grain boundary. Acta Materialia 49:6, pages 1079-1085.
Crossref
Yan-Quan Fen & Chong-Yu Wang. (2001) Electronic effects of nitrogen and phosphorus on iron grain boundary cohesion. Computational Materials Science 20:1, pages 48-56.
Crossref
Gang Zhou, Wenhui Duan & Binglin Gu. (2001) First-principles study on morphology and mechanical properties of single-walled carbon nanotube. Chemical Physics Letters 333:5, pages 344-349.
Crossref
M. Guttmann. 2001. Encyclopedia of Materials: Science and Technology. Encyclopedia of Materials: Science and Technology 1 8 .
W. T. Geng, A. J. Freeman, R. Wu & G. B. Olson. (2000) Effect of Mo and Pd on the grain-boundary cohesion of Fe. Physical Review B 62:10, pages 6208-6214.
Crossref
Witold Lojkowski & Hans-Jörg Fecht. (2000) The structure of intercrystalline interfaces. Progress in Materials Science 45:5-6, pages 339-568.
Crossref

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.