Physics Publications by Zbigniew.

1. Z. Koziol, A. Golnik, Study of dynamic magnetic susceptibility in spin glass CdMnTe by means of Faraday rotation, Acta Physica Polonica A71 159 (1987)
2. J. Piechota, Z. Koziol, A. Pajaczkowska, H. Szymczak, AC Susceptibility in Ceramic and Powdered YBaCuO, Phys. Stat. Sol. A113, 151 (1989). PDF
3. Z. Koziol, J. Piechota, H. Szymczak, Superconducting Glass-Phase Diagram for Ceramic YBaCuO, J. de Physique, 50 3123 (1989). PDF
4. Z. Koziol, Frequency Dependent Susceptibility of the Ceramic YBaCuO -the Spin-Glass-Like Approach, Physica C 159, 281 (1989). PDF
5. Z. Koziol, Higher Harmonics in the ac Susceptibility Measurements of High Tc Superconductors, in Proc. Europ. Conf. HTc Thin Films and Single Crystals, Progress in High Temperature Superconductivity - Vol 24, ed. by Gorzkowski, W., Gutowski, M., Reich, A., and Szymczak, H., World Scientific, Singapore (1990).
6. J. Piechota, Z. Koziol, H. Szymczak, A. Pajaczkowska, Critical Current and Lower Critical Fields in YBaCuFeO Physica Scripta 42 109 (1990). PDF
7. A. Wisniewski, M. Baran, Z.Koziol, P. Przyslupski, J. Piechota, R. Puzniak, A. Pajaczkowska, M. Pekala, B. Pytel, K. Pytel, The influence of fast neutron irradiation on the intra- and intergrain properties of the polycrystalline BiPbSrCaCuO system. Physica C 170 333 (1990). PDF
8. Z. Koziol, A. Mongird-Gorska, Frequency dependent susceptibility of polycrystalline BiPbSrCaCuO. Solid State Commun. 77 265 (1991). PDF
9. M. C. Aronson, T. Vorenkamp, Z. Koziol, K. Bakker, A. de Visser, J. J. M. Franse, Impurity effects in superconducting UPt3. J. Appl. Phys. 69 5487 (1991). PDF
10. J. N. Li, K. Kadowaki, Z. Tarnawski, Z. Koziol, and J. J. M. Franse, Magnetic field induced anisotropic resistive transition in single crystalline YBaCuO and BiSrCaCuO. Physica C 185-189 1836 (1991). PDF
11. Z. Koziol, K. Bakker, A. de Visser, J. J. M. Franse, Anisotropy of superconducting properties of UPt3 close to Tc. Physica C 185-189 2633 (1991). PDF
12. Z. Koziol, J. J. M. Franse, P. de Chatel, T. Vorenkamp, K. Bakker, A. de Visser, A. A. Menovsky, Unconventional superconductivity in UPt3: low field ac susceptibility studies. Physica C 192 284 (1991). PDF
13. Z. Koziol, Z. Tarnawski, J.J.M. Franse, Study of the Remanent Magnetization of Bi2Sr2CaCu2O8 Single Crystals by Means of a Hall Probe. Solid State Commun. 85 (1993) 991. PDF
14. Z. Koziol, P. de Chatel, J.J.M. Franse, Z. Tarnawski, and A.A. Menovsky, Evidence for Nonlinear Flux Diffusion from Magnetization Relaxation in Bi2Sr2CaCu2O8 Single Crystals, Physica C212, (1993) 133. PDF
15. Z. Koziol, J.J.M. Franse, A.A. Menovsky,Unconventional superconductivity in UPt3: frequency dependent ac susceptibility, in Proc. of Int. Conf. on the Physics of Transition Metals: eds P.M. Oppeneer and J. Kubler, p. 18, (1993), World Scientific. PDF
16. T. Vorenkamp, M.C. Aronson, Z. Koziol, K. Bakker, J.J.M. Franse, and J.L. Smith, Substitution studies and the nature of the superconductivity in UPt3. Phys. Rev. B48 (1993) 6373. PDF
17. Z. Koziol and P. F. de Châtel, Non-Linear Diffusion Equation and Relaxation Processes in Solids, IEEE Trans. Magn. 30 (1994) 1169. PDF
18. Z. Koziol, A.A. Menovsky, K. Bakker, J. J. M. Franse, Anisotropic Low-Field Magnetization of the Heavy-Fermion Superconductor URu2Si2. IEEE Trans. Magn. 30 (1994) 1193. PDF
19. Z. Koziol and J.J.M. Franse, Application of the Hall-Probe Technique for Magnetization Measurements of Superconductors. IEEE Trans. Magn. 30 (1994) 1172. PDF
20. H. Nakotte, Z. Koziol, K. Bakker, F.R. de Boer, A.V. Andreev, High-field magnetization of the heavy-fermion superconductor UNi2Al3. IEEE Trans. Magn. 30 (1994) 1199. PDF
21. Z. Koziol, J.J.M. Franse, P.F. de Châtel and A.A. Menovsky, Magnetization of a superconductor - Results from the critical state model, Phys. Rev. B50 (1994) 15978. PDF
22. Z. Koziol, J.J.M. Franse and A.A. Menovsky, AC susceptibility and anisotropic flux pinning in unconventional superconductor UPt3, Physica C 235-240 (1994) 2445. PDF
23. Z. Koziol, J.J.M. Franse and A.A. Menovsky, Anisotropic Flux Pinning and Upper Critical Fields of the Heavy-Fermion Superconductor URu2Si2. J. Magn. Magn. Mat. 140-144 (1995) . PDF (manuscript) or PDF (published version)
24. M. Yewondwossen, Z. Koziol and R.A. Dunlap, Mossbauer Effect and Electronic Transport Studies of Icosahedral Al50Pd10Mn25-xFexB15 Alloys, J. Appl. Phys. 79 5992 (1996) PDF
25. M. Yewondwossen, Z. Koziol, Z. Yang, M.Foldeaki and R.A. Dunlap, Magnetic and Electronic Properties of the Magnetically Ordered Quasicrystalline Alloys Al70-xPd15Mn15Fex , J. Appl. Phys. 79 5995 (1996) PDF
26. Z. Koziol and R.A. Dunlap, Magnetostriction of a superconductor: results from the critical-state model, J. Appl. Phys. 79 4679 (1996) PDF; HTML
27. Z. Koziol and R.A. Dunlap, Nonlinear flux diffusion and AC susceptibility of superconductors -exact numerical results J. Appl. Phys. 79 4662 (1996) PDF; HTML
28. D. Bahadur, M. Yewondwossen, Z. Koziol, M. Foldeaki, and R.A. Dunlap, Physical properties of the giant magnetoresistive perovskite system La-Er-Ca-Mn-O J. Phys.: Condens. Matter 8 5235 (1996) PDF
29. D. Bahadur, M. Foldeaki, S.K. Mandal, M.H. Yewondwossen, Z. Koziol, and R.A. Dunlap, Magnetoresistance studies of La-M-Ca-Mn-O (M=Er, Yb, Bi) perovskites, J. Alloys and Compunds, 256 (1997) 76 PDF
30. S. I. Matyukhin, Z. Koziol and S. N. Romashyn, The radiative characteristics of quantum-well active region of AlGaAs lasers with separate-confinement heterostructure (SCH), arXiv:1010.0432v1 [cond-mat.mtrl-sci] (2010), PDF; SOURCE
31. Матюхин С.И., Козил З.Ж., Ромашин С.Н., Спектральные характеристики полупроводниковых AlGaAs лазеров с двойной гетероструктурой и раздельным ограничением, Фундаментальные и прикладные проблемы техники и технологии, 6 (284), (2010), С.20-27.
32. Матюхин С.И., Козил З.Ж., Г.Р. Магомедов, Д.О. Малый, Ромашин С.Н., Зависимость характеристик полупроводникового ДГС РО лазера на основе AlGaAs от корцентрации алюминия в области водновода и эмиттеров, Фундаментальные и прикладные проблемы техники и технологии, № 3 (287), (2011), C.26-35. Работа выполнена в рамках ФЦП «Научные и научно-педагогические кадры инновационной России» (ГК № П2514).
33. Матюхин С.И., Козил З.Ж., Магомедов Г.Р., Малый Д.О., Ромашин С.Н. Длина волны полупроводникового ДГС РО лазера на основе AlGaAs с квантоворазмерной активной областью. Ученые записки Орловского государственного университета. 2011. №3 (41). Стр.74-83. PDF. Работа выполнена в рамках ФЦП «Научные и научно-педагогические кадры инновационной России» (ГК № П2514)
34. Матюхин С.И., Козил З.Ж., Ромашин С.Н., Физические основы микроэлектроники. Имитационное моделирование полупроводниковых лазеров. Учебное пособие,- Орел: Изд-во ОрелГТУ, (2011). 90 с. PDF. Работа выполнена в рамках ФЦП «Научные и научно-педагогические кадры инновационной России» (ГК № П2514)
35. Матюхин С.И., Козил З.Ж., Ромашин С.Н. Спектральные характеристики полупроводниковых AlGaAs лазеров с двойной гетероструктурой и раздельным ограничением. Фундаментальные и прикладные проблемы техники и технологии. 2010. №6 (284). С.20-27. Работа выполнена в рамках ФЦП «Научные и научно-педагогические кадры инновационной России» (ГК № П2514)
36. Матюхин С.И., Козил З.Ж., Г.Р. Магомедов, Д.О. Малый, Ромашин С.Н., Компютерное моделирование характеристик полупроводникового ДГС РО лазера на основе AlGaAs в зависимости от положения активной области в волноводе, Информационные системы и технологии 5 (67), (2011)
37. Z. Koziol and S. I. Matyukhin, Doping effects in AlGaAs lasers with separate confinement heterostructures (SCH). Modeling optical and electrical characteristics with Sentaurus TCAD, arXiv:1106.2501v1 [physics.comp-ph] (2011), PDF; SOURCE
38. Zbigniew Koziol, and Sergey I. Matyukhin, Modified exponential I(U) dependence and optical effciency of AlGaAs SCH lasers in computer modeling with Synopsys TCAD, arXiv:1107.4668v1 [cond-mat.mtrl-sci] (2011), PDF; SOURCE
39. Zbigniew Koziol, and Sergey I. Matyukhin, The effects of multiply quantum wells (MQW) on optical and electrical characteristics of AlGaAs lasers with separate confinement heterostructures (SCH), arXiv:1108.6231v1 [cond-mat.mtrl-sci] (2011), PDF; SOURCE
40. Zbigniew Koziol, Quantum-well states and discontinuities in opto-electrical characteristics of SCH lasers, arXiv:1112.0139v1 [cond-mat.mtrl-sci] (2011), PDF; SOURCE
41. Zbigniew Koziol, Sergey I. Matyukhin, The Lasing Wavelength of QW Active Region of AlGaAs SCH Lasers, Romanian Journal of Physics, Volume 57, Number 3-4, 2012, pp.711-719. PDF.
42. Матюхин С.И., Козил З.Ж., Зависимость характеристик полупроводникового ДГС РО лазера на основе AlGaAs от ширины квантоворазмерной активной области. Наноинженерия. 2012. №5. С.14-17. PDF.
43. Zbigniew Koziol, Sergey I. Matyukhin, Evgeniya A. Buduleva, The role of quantum-well states and carrier scattering times on discontinuities in opto-electrical characteristics of SCH lasers, arXiv:1302.0370 [cond-mat.mtrl-sci] (2013), PDF; SOURCE
44. Zbigniew Koziol, Sergey I. Matyukhin, Evgeniya A. Buduleva, The role of quantum-well states and carrier scattering times in discontinuities of opto-electrical characteristics of SCH lasers, Optica Applicata, Vol. XLIV, No. 1, pp.135-146, 2014, PDF
45. Zbigniew Kozioł, Dynamics of Users Activity on Web-Blogs, Acta Physica Polonica 129, pp. 1060-1063, 2016. PDF, and an early version: arXiv:1410.0828v1 [physics.soc-ph]
46. Zbigniew Kozioł, Grzegorz Gawlik, Jacek Jagielski, Van der Waals interlayer potential of graphitic structures: from Lennard-Jones to Kolmogorov-Crespy and Lebedeva models, Chinese Physics B 28 (9), pp. 096101-1--096101-8, 2019. PDF, and an early version: arXiv:1803.05162 [cond-mat.mes-hall]
47. Zbigniew Koziol, A method of numerical evaluation of some physical properties of Van der Waals structures, J Clin Exp Oncol7 p. 57, 2018 or this PDF. See also this YouTube movie. DOI: 10.4172/2324-9110-C5-021.
48. Zbigniew Kozioł, Number of equidistant neighbors on honeycomb lattice, J. Phys. Commun. 4 075003 J. Phys. Commun. 4 p. 075003, 2020, and Supplementary materials; arXiv:2004.11840 [cond-mat.mes-hall]; DOI: 10.1088/2399-6528/aba035.
49. Hamza Hebal, Zbigniew Kozioł, Sefer Bora Lisesivdin, Robert Steed, General-purpose open-source 1D self-consistent Schrödinger-Poisson Solver: Aestimo 1D, Computational Materials Science 186 p. 110015, 2021. DOI: 10.1016/j.commatsci.2020.110015

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