|
|
|
| A Method for Calculating the Dislocation Contrast Factor in X-ray Diffraction Profile Analysis |
| HU Qiu-shi,ZHAO Feng,FU Hua |
| Institute of Fluid Physics, China Academy of Engineering Physics, Mianyang, Sichuan 621900, China |
|
|
|
|
Abstract The displacement field produced by dislocations was calculated by using Teodosiu anisotropic elastic theory.The formulas for calculating the dislocation contrast factors of different slip systems were established.Taking the cubic crystal as example, the calculation process was simplified, and the contrast factors of dislocations distributed in 12 slip systems under 8 diffraction indices in f.c.c Cu and b.c.c Fe were given.The calculation results were compared with those in the literature.X-ray diffraction experiments were carried out on oxygen free copper subjected to different quasi-static compression loading strains.The role of the contrast factor in eliminating the anisotropy broadening of the diffraction profiles was described.The subgrain size, screw dislocation ratio and the dislocation density in the sample were obtained by using line profile analysis.
|
|
Received: 16 August 2017
Published: 05 September 2018
|
|
|
|
|
|
[1]Ungar T, Gubicza J, Ribarik G, et al. Crystallite size distribution and dislocation structure determined by diffraction profile analysis: principles and practical application to cubicand hexagonal crystals[J]. Journal of Applied Crystallography,2001,34(3):298-310.
[2]Chen Y Z, Csiszar G, Cizek J, et al. On the formation of vacancies in α-ferrite of a heavily cold-drawn pearlitic steel wire[J]. Scripta Materialia,2011,64(5):390-393.
[3]Hu Q S, Zhao F, Fu H, et al. Dislocation density and mechanical threshold stress in OFHC copper subjected to SHPB loading and plate impact[J]. Materials Science and Engineering:A,2017,695:230-238.
[4]Krivoglaz M A. X-ray and Neutron Diffraction in Non-ideal Crystals[M]. Berlin: Springer-Verlag Press,1996.
[5]Groma I, Borbély A. X-ray line broadening due to an inhomogeneous dislocation distribution[J]. Physical Review B,1998,57(13):7535-7542.
[6]Klimanek P, Kuzel R. X-ray diffraction line broadening due to dislocation in non-cubic materials.I.general considerations and the case of elastic isotropy applied to hexagonal crystals[J]. Journal of Applied Crystallography,1988,21(1):59-66.
[7]Stroh A N. Dislocations and cracks in anisotropic elasticity[J]. Philosophical Magazine,1958,3(30):625-646.
[8]Teodosiu C. Elastic Models of Crystal Defects[M]. Berlin: Springer-Verlag Press,1982.
[9]Martinez-Garcia J, Leoni M, Scardi P. Analytical expression for the dislocation contrast factor of the <001>{100} cubic slip-system: application to Cu2O[J]. Physical Review B,2007,76:174117.
[10]Ungar T, Dragomir I, Revesz A, et al. The contrast factors of dislocations in cubic crystals: the dislocation model of strain anisotropy in practice[J]. Journal of Applied Crystallography,1999,32(5):992-1002.
[11]吴家龙.弹性力学[M]. 北京:高等教育出版社,2001.
[12]鲍静,冯晓娟,林鸿,等.可变温的固体材料弹性参数测量系统研究[J].计量学报,2015,36(5):449-454.
[13]Dragomir I C, Ungar T. The dislocations contrast factors of cubic crystals in the Zener constant range between zero and unity[J]. Powder Diffraction,2002,17(2):104-111.
[14]赖振宇,邹秋林,卢忠远,等.Rietveld全谱拟合方法对磷酸镁水泥水化产物的定量分析研究[J].计量学报,2014,35(4):398-402.
[15]Stokes A R. A numerical Fourier-analysis method for the correction of widths and shapes of lines on X-ray powder photographs[J]. Proceedings of the Physical Society,1948,61(4):382-391. |
|
|
|
2018, Vol. 39 
