Journal
[39] Group theoretical methods in solid state Physics of SnO2 [pdf]
E. Jekal, S. Park, Material Sci & Eng. 6(3), 111 (2022)
[38] Computational method for solving rubik’s cube
T. Lee and E. Jekal, Current advanced research, 11(2), 298 (2022)
[37] Experimental Methodology to Find the Center of Gravity of a Solid
J. je and E. Jekal, J. Eng, Res. Sci.1(3), 148 (2022)
[36] External Environment Dependent Spin and Orbital Exchange Interactions
E. Jekal, J. Mod. Sim. Mater. 3(1), 79 (2020). [pdf]
[35] An insight of a needle free injector with magnetic material
E. Jekal, Evolutions. Mech. Eng. 3(2), 1 (2020). [pdf]
[34] Machine learning approach for prediction of glass forming ability in bulk metallic glasses,
E. Jekal, Glob. J. Eng. Sci. 4(2), 1 (2019).
[33] MnIr thickness dependence of exchange coupling properties in CoFe/MnIr bilayers
E. Jekal, IOSR JAP. 6, 20 (2019). [pdf]
[32] First-principles study on the magntic properties of Gd doped Bithmuth-Telluride,
D. jacobsen, E. Jekal, Mod. Concept Material Sci. 2(1), 1 (2019). [pdf]
[31] First principle studies on magnetism of perovskite structured CoFeCl3 film,
E. Jekal, Glob. J. Eng. Sci. 4(2), 5 (2019). [pdf]
[30] Surface termination and thickness dependent magnetic properties of SmCo5 film,
E. Jekal, Mod. Concept Material Sci. 2(3),1 (2019). [pdf]
--------------------------officially changed name----------------------
[29] Perpendicular exchange bias of Co/Ni multilayers adjacent to antiferromagnetic FeRh layer
S. Jekal and D. Phuong, J. Multidis. Res. Rev. 1(2), 13 (2019). [pdf]
[28] Links between mechanical properties and local atomic structures of Cu-Zr bulk metallic glasses,
S. Jekal, Res. Dev. Material Sci. 12(2), 1260 (2019). [pdf]
[27] Magnetism and magnetocrystalline anisotropy of Co/Fe(001) surface: a first principles study,
S. Jekal, A. Danilo, Mod Concept Material Sci. 2(1), 1 (2019). [pdf]
[26] Dependence of atomic thickness on magnetocrystalline anisotropy and interfacial conditions in SmCo5/Sm2Co17 multilayer,
S. Jekal, Materials, 12, 56 (2019). [pdf]
[25] First-principles prediction of skyrmionic phase behavior in GdFe2 films capped by 4d and 5d transition metals,
S. Jekal, Appl. Sci. 9, 630 (2019).
[24] Exchange interactions and Curie temperature of Ce-substituted SmCo5,
S. Jekal, Condens. Matter, 4, 11 (2019).
[23] Geometrical characterization of atomic structure of Cu-Zr bulk metallic glasses,
S. Jekal, J. F. Loeffler, and P. M. Derlet, Swiss National Foundation (SNF) grant No. 200021-165527 (2018).
[22] First principles calculations on magnetism of CrPt3(001) thin films,
T. Jeong, S. Jekal, S. H. Rhim, and S. C. Hong, J. Kor. Magn. Soc. 27, 41 (2017).
[21] First principle studies on magnetism of perovskite structured CoFeX3(X=O,F,S,Cl),
S. Jekal and S. C. Hong, J. Kor. Magn. Soc. 26, 176 (2016).
[20] Electron beam-formed ferromagnetic defects on MoS2 surface along 1T phase transition,
S. W. Han, Y. Park, Y. H. Hwang, S. Jekal, M. Kang, G. Lee, W. G. Lee, K. S. Kim, W. Yang, and S. C. Hong, Scientific Reports, 6, 38730 (2016).
[19] First-principles calculations on magnetism of 1H/1T boundary in monolayered MoS2,
S. Jekal and S. C. Hong, J. Kor. Magn. Soc. 26, 71 (2016).
[18] Magnetism of asymmetrically terminated FeRh(001) thin films: A first-principles study,
S. Jekal, S. H. Rhim, and S. C. Hong, IEEE Trans. Magn. 52, 7004503 (2016).
[17] Surface-termination dependent magnetism and strong perpendicular magnetocrystalline anisotropy of a FeRh (001) thin film,
S. Jekal, S. H. Rhim, S. C. Hong, W. J. Son, and A. B. Shick, Phys. Rev. B 92, 064410 (2015).
[16] Thickness effect on magnetocrystalline anisotropy of a Co/Pd(111) films: A density functional study,
S. Jekal, S. H. Rhim, O. Kwon, and S. C. Hong, J. Appl. Phys. 117, 17E105 (2015).
[15] Magnetocrystalline anisotropy of d0-magnetic material NaN (001) thin films: A density functional study,
S. Jekal, O. Kwon, S. C. Hong, and J. I. Lee, J. Nanosci. Nanotechnol. 15, 2356 (2015).
[14] Magnetism and magnetocrystalline anisotropy of CoFe thin films: A first-principles study,
E. G. Kim, S. Jekal, O. Kwon, and S. C. Hong, J. Kor. Soc. Magn. 24, 35 (2014).
[13] Magnetic properties of thin films of a magnetocaloric material FeRh,
S. Jekal, O. Kwon, and S. C. Hong, Proceeding to EDISON Nano Physics Competition, 2, 96 (2013). [pdf]
Preprint
[12] First principle studies on magnetism of perovskite structured CoFeCl3 film
E. Jekal
[11] A first-principles study on the surface magnetism of the CsCl structured CoX (X = Ti, V, Nb) (001) surface
E. Jekal
[10] Atomistic simulation for rejuvenation of Cu-Zr metallic glasses by strain,
E. Jekal, DOI: 10.20944/preprints201911.0344 (2019).
[9] Magnetocrystalline anisotropy of MoS2 governed by sliding S atom,
E. Jekal, M. Jacobsen, arXiv preprint arXiv:2895349 (2019).
[8] Prediction magneitocrystalline anisotropy Fe-Rh thin films via machine learning,
E. Jekal, H. Park, arXiv preprint arXiv:1908.04762 (2019).
[7] Strain controllable magnetocrystalline anisotropy in FeRh/Mgo bilayers,
H. Hoffmann and E. Jekal, arXiv preprint arXiv:1908.04761 (2019).
[6] Strain and thickness effects on magneticrystalline anisotropy of CoFe(011) films,
E. Jekal, D. Phuong, arXiv preprint arXiv:1906.09153 (2019).
[5] Increased perpendicular magnetocrystalline anisotropy governed by magnetic boundary in an asymmetrically terminated FeRh(001) thin film,
S. Jekal, arXiv preprint arXiv:1906.07566 (2019).
[4] Pushing the limits of magnetic anisotropy in the Sm-Co system,
S. Jekal, M. Charilaou, and J. F. Loeffler, arXiv preprint arXiv:1807.09257 (2018).
Thesis
[3] Doctoral dissertation, Magnetically and geometically atomic properties of materials (2020).
[2] Master thesis, Magnetic controllability of FeRh: A first principles study (2016).
[1] Bachelor thesis, First principles study of magnetic properties of NaN(001), Co/Pd(111) and Cofe(011) thin films (2014).