Restricted accessResearch articleFirst published online 2025
A novel singular integral operator technique for analyzing semipermeable four collinear cracks in a magneto-electro-elastic solid based on the EMPS model
This manuscript introduces a novel analytical technique using singular integral operators (SIOs) to study the strip electric-magnetic polarization saturation (EMPS) model with four collinear cracks, including two pairs of symmetrical unequal cracks, embedded in an infinite magneto-electro-elastic (MEE) solid. By applying the EMPS model and the distributed dislocation technique (DDT) while leveraging symmetry, we formulate singular integral equations for the coupled mechanical, electrical, and magnetic cracks based on their dislocation density functions. These equations are then transformed into Cauchy-type singular integral equations using nonlinear transformation. Since the reduced system of singular integral equations is defined over two disjoint intervals, an SIO-based technique is developed for the problem where Cauchy-type SIOs and inverse operators for each dislocation density function are defined, and then using their identities, the analytical solutions for the unknown dislocation density functions are derived after simplification. Iterative methods are employed to determine semipermeable crack-face conditions and the lengths of saturated zones. Numerical analysis shows that the distances between cracks and the crack length ratio significantly affect the lengths of saturated zones, crack tip opening potential (CTOP), crack tip opening induction (CTOI), crack opening displacement (COD), and the local stress intensity factor (LSIF), while inter-crack distance variations have a negligible impact on crack-face conditions. Validation of the results for the specific cases of the stated problem confirms the accuracy and efficacy of the developed SIO-based technique and the analytical solutions.
TheocarisPS. Dugdale models for two collinear unequal cracks. Engng Fract Mech1983; 18(3): 545–559.
2.
CollinsRACartwrightDJ. An analytical solution for two equal-length collinear strip yield cracks. Engng Fract Mech2001; 68(7): 915–924.
3.
NishimuraT. Strip yield analysis of two collinear unequal cracks in an infinite sheet. Engng Fract Mech2002; 69(11): 1173–1191.
4.
XuWWuXRWangH. Weight functions and strip yield solution for two equal-length collinear cracks in an infinite sheet. Engng Fract Mech2011; 78(11): 2356–2368.
5.
HasanS. Application of modified Dugdale model to two pairs of collinear cracks with coalesced yield zones. Appl Math Model2016; 40(4): 3381–3399.
6.
HasanS. Modified Dugdale model for four collinear straight cracks with coalesced yield zones. Theor Appl Fract Mech2016; 85: 227–235.
7.
AkhtarNHasanS. Assessment of the interaction between three collinear unequal straight cracks with unified yield zones. AIMS Mater Sci2017; 4(2): 302–316.
8.
LiuZXXuWYuY, et al. Weight functions and stress intensity factors for two unequal-length collinear cracks in an infinite sheet. Engng Fract Mech2019; 209: 173–186.
9.
ZhangBXuWWuX, et al. Stress intensity factors and plastic zones of stiffened panels with multiple collinear cracks. Theor Appl Fract Mech2020; 110: 102816.
10.
ZhangXLongQZhengT, et al. Theoretical analysis of stress intensity factor for two unequal collinear cracks subjected to internal pressure and compressive stress. J Mech2021; 37: 584–596.
11.
BhargavaRRJangidK. Strip electro-mechanical yielding model for piezoelectric plate cut along two equal collinear cracks. Appl Math Model2013; 37(22): 9101–9116.
12.
BhargavaRRJangidK. Strip-saturation model for piezoelectric plane weakened by two collinear cracks with coalesced interior zones. Appl Math Model2013; 37(6): 4093–4102.
13.
BhargavaRRJangidK. Strip-coalesced interior zone model for two unequal collinear cracks weakening piezoelectric media. Appl Math Mech2014; 35: 1249–1260.
14.
SinghSSharmaKBhargavaRR. Analytical solution for two equal collinear modified strip saturated cracks in 2-D semipermeable piezoelectric media. ZAMM2019; 99(9): e201800244.
15.
SinghSSharmaKBhargavaRR. Modified strip saturated models for two equal collinear cracks with coalesced zones in piezoelectric media. Appl Math Mech2019; 40: 1097–1118.
16.
SinghSSharmaKBuiTQ. Closed-form solutions for modified polarization saturated models in two unequal collinear cracked piezoelectric media considering coalesced interior zones. Eur J Mech A Solids2021; 89: 104313.
17.
LiuHT. Dynamic intensity factors for multiple permeable cracks in piezoelectric materials. ZAMM2020; 100(9): e201900344.
18.
SharmaKSinghSBuiTQ. Simplified numerical algorithms for generalized strip saturated two equal collinear cracks in piezoelectric media using distributed dislocation technique. ZAMM2023; 103(11): e202300004.
19.
HasanSAkhtarN. Strip electro-mechanical yield model for three equal straight collinear cracks in piezoelectric materials. Eur J Mech A Solids2024; 106: 105335.
20.
GaoCFKesslerHBalkeH. Crack problems in magnetoelectroelastic solids. Part II: general solution of collinear cracks. Int J Eng Sci2003; 41(9): 983–994.
21.
TianWYGabbertU. Multiple crack interaction problem in magnetoelectroelastic solids. Eur J Mech A Solids2004; 23(4): 599–614.
22.
ZhouZGZhangPWWuLZ. Solutions to a limited-permeable crack or two limited-permeable collinear cracks in piezoelectric/piezomagnetic materials. Arch Appl Mech2007; 77: 861–882.
23.
ZhouZGZhangPWLiGQ. Basic solution of four parallel non-symmetric permeable mode-iii cracks in a piezoelectric/piezomagnetic composite plane. Philos Mag2008; 88(8): 1153–1186.
24.
SinghBMRokneJDhaliwalRS. Closed-form solutions for two anti-plane collinear cracks in a magnetoelectroelastic layer. Eur J Mech A Solids2009; 28(3): 599–609.
25.
LiYDLeeKY. Collinear unequal crack series in magnetoelectroelastic materials: mode I case solved via new real fundamental solutions. Engng Fract Mech2010; 77(14): 2772–2790.
26.
ZhongXC. Closed-form solutions for two collinear dielectric cracks in a magnetoelectroelastic solid. Appl Math Model2011; 35(6): 2930–2944.
27.
VermaPRVermaRR. Magneto-electro-elastic analysis for two mode-III semi-permeable collinear cracks in piezo-electro-magnetic strip. Int J Math Model Numer Optim2020; 10(2): 187–213.
28.
JangidK. A study of electric and magnetic polarizations on a piezoelectromagnetic media weakened by two unequal collinear semi-permeable cracks. Int J Comput Method Eng Sci Mech2020; 21(6): 292–311.
29.
JangidK. Magnetic-saturation zone model for two semipermeable cracks in magneto-electro-elastic medium. Int J Comput Method Eng Sci Mech2018; 19(2): 129–137.
30.
ZhaoMZhangQFanC, et al. Semi-permeable crack analysis in a 2D magnetoelectroelastic medium based on the EMPS model. Mech Res Commun2014; 55: 30–39.
31.
VermaPR. Magnetic-yielding zone model for assessment of two mode-III semi-permeable collinear cracks in piezo-electro-magnetic strip. Mech Adv Mater Struct2022; 29(11): 1529–1542.
32.
KumarASharmaKBuiTQ. Singular integral method based closed form solution for moving EMPS model in semipermeable two-equal-collinear cracked MEE material. ZAMM J Appl Math Mech2024; 104: e202300731.
33.
KumarASharmaKBuiTQ. Moving EMPS model for semipermeable two equal collinear interface cracks in dissimilar magneto-electro-elastic materials. Mech Adv Mater Struct2024; 32: 873–892.
34.
MonfaredMMAyatollahiM. Elastodynamic analysis of a cracked orthotropic half-plane. Appl Math Modell2012; 36(6): 2350–2359.
35.
HejaziAAAyatollahiMBagheriR, et al. Dislocation technique to obtain the dynamic stress intensity factors for multiple cracks in a half-plane under impact load. Arch Appl Mech2014; 84: 95–107.
36.
MonfaredMMBagheriR. Multiple interacting arbitrary shaped cracks in an FGM plane. Theor Appl Fract Mech2016; 86: 161–170.
37.
SourkiRIlyaeiSBastanfarM, et al. Multiple cracks analysis in a FG orthotropic layer with FGPM coating under anti-plane loading. J Braz Soc Mech Sci Eng2018; 40: 1–12.
38.
BagheriRAyatollahiMMirzaeiAM, et al. Multiple defects in a piezoelectric half-plane under electro-elastic in-plane loadings. Theor Appl Fract Mech2019; 103: 102316.
39.
HosseiniSMBagheriRMonfaredMM. Transient response of several cracks in a nonhomogeneous half-layer bonded to a magneto-electro-elastic coating. Theor Appl Fract Mech2020; 110: 102821.
40.
MonfaredMMBagheriR. In-plane stress analysis in a cracked functionally graded piezoelectric plane. Mech Based Design Struct Machines2023; 51(8): 4508–4534.
41.
ChakrabartiAGeorgeAJ. Solution of a singular integral equation involving two intervals arising in the theory of water waves. Appl Math Lett1994; 7: 43–47.
42.
ChakrabartiASahooT. Solution of singular integral equations with logarithmic and Cauchy kernels. Proc Indian Acad Sci Math Sci1996; 106: 181–196.
43.
TricomiFG. Integral equations. Chelmsford, MA: Courier Corporation, 1985.
44.
EstradaRKanwalRP. Singular integral equations. Cham: Springer, 2012.
45.
KumarASharmaKBuiTQ. Singular integral based closed-form solutions for modified EMPS models in semipermeable magneto-electro-elastic materials. Appl Math Modell2024; 129: 673–695.
46.
HillsDAKellyPADaiDN, et al. Solution of crack problems. Cham: Springer, 1996.
