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8. Datsyshyn, P. & PANASYUK, V. V. (2001). Wear, 251, 1347-1355.
60. Datsyshyn, O. P. & PANASYUK, V. V. (2001). Pitting of the rolling bodies contact surface. Wear, 251, 1347-1355.
62. PANASYUK, V. V., Datsyshyn, O. P. & Marchenko, H. P. (1995). The crack propagation theory under rolling contact. Eng. Fract. Mech., 52, 179-191.
12. PANASYUK, V. V., Ostash, O. P. & Kostyk, E. M. (1985). Initiation of fatigue cracks near stress concentrators. Fiz.-Khim. Mekh. Mater., 6, 3-10.
16. V. V. PANASYUK (Ed.), Fracture Mechanics and Strength of Materials [in Russian], A Handbook in 4 volumes, Vol. 4: O. N. Romaniv, S. Ya. Yarema, G. N. Nikiforchin, et al., Fatigue and Cyclic Crack Resistance of Structural Materials, Naukova Dumka, Kiev (1990).
2. Bulyk, I. I., Denys, R. V. & PANASYUK, V. V. (2001). The HDDR process and hydrogen-sorption properties of didymium-alumi- num-iron-boron alloy (Dd12 3 AI12 F.79.4136)1. Fiz. -Khim. Mekh. Mater., 37, 4, 15-20.
2. Datsyshyn, O. P. & PANASYUK, V. V. Pitting of the rolling bodies contact surface. Wear, 251, 1347-1355, 2001.
3. PANASYUK, V. V. 0. P. Datsyshyn, and H.P. Marchenko, "To crack propagation theory under rolling contact, " Eng. Fract. Mech., 52, No. 1, 179-191, 1995.
10. PANASYUK, V.V., `The Limit Equilibrium of the Brittle Solid: with Cracks', (Kiev,1968) [only available in Russian].
15. Ostash, O. P., PANASYUK, V V and Kostyk, E. M. (1999) A phenomenological model of fatigue macrocrack initiation near stress concentrators. Fatigue Fract. Engng Mater Struct. 22, 161-172.
18. Yartys, V. A., Harris, I. R. & PANASYUK, V. V. Novel metal hydrides. A review. Mat. Sci., 29, 100-116, 2001.
Title Modification of Dugdale model to include the work hardening and in- and out-of-plane constraints.
2. Leonov, M.Y. & PANASYUK, V.V. (1959). Growth of the minute cracks in a brittle body. Prikhladnaya Mekh, 5, 391-401.
3. PANASYUK, V.V. On the theory of cracks spreading during deformation of a brittle body. Dop Akad Nauk Ukrain RSR 1960;9:1180-8 [in Ukrainian]. .
Title X-ray and metallographic examinations of phase transformations during Solid-HDDR in ferromagnetic alloy of didymium-iron-boron system.
Title Features of the HDDR process in R-Fe-B ferromagnetic alloys (R is a mixture of Nd, Pr, Ce, La, Dy and others).
References 1. V. V. PANASYUK, Mechanics of Quasibrittle Fracture of Materials [in Russian], Naukova Dumka, Kiev (1991).
2. V. V. PANASYUK, "An outline of the development of fracture mechanics and strength-of materials investigations," in: Investigations of Fracture, Strength, and Integrity of Materials and Structures, Karpenko Physicomechanical Institute, Ukrainian Acade my of Sciences, Lviv (1993), pp. 7-48.
4. V. V. PANASYUK, "Fracture mechanics of materials -a new scientific trend," in: I. K. Pokhodnya (editor), Promising Materials and Technologies [in Ukrainian], Vol. 2, Vydavnych. Dim, Kiev (2003), pp. 501-524.
5. V. V. PANASYUK (editor), Fracture Mechanics and Strength of Materials. A Handbook [in Russian], Vols. 1-4, Naukova Dumka, Kiev (1988-1990); Vol. 1, V. V. PANASYUK, A. E. Andreikiv, and V. Z. Parton, Foundations of Fracture Mechanics of Materials [in Russian], Naukova Dumka, Kiev (1988); Vol. 2, M. P. Savruk, Stress Intensity Factors in Cracked Bodies [in Russian], Naukova Dumka, Kiev (1988); Vol. 3, S. E. Kovchik and E. M. Morozov, Characteristics of the Short-Term Crack Resistance of Materials and Methods for Their Determination [in Russian], Naukova Dumka, Kiev (1988); Vol. 4, O. N. Romaniv, S. Ya. Yarema, G. N. Nikiforchin, N. A. Makhutov, and M. M. Stadnik, Fatigue and Cyclic Crack-Growth Resistance of Structural Materials [in Russian], Naukova Dumka, Kiev (1990).
7. V. V. PANASYUK, O. E. Andreikiv, L. M. Lobanov, D. M. Teplin, and N. V. Kuzyak, Fracture Mechanics: Achievements ana Problems (Book-Survey MKR-8) [in Ukrainian], Karpenko Physicomechanical Institute, Ukrainian Academy of Sciences, Lviv (1994).
8. V. V. PANASYUK, Deformation Criteria in Fracture Mechanics of Materials [in Ukrainian], Karpenko Physicomechanical Institute, Ukrainian Academy of Sciences, Lviv (1993).
11. PANASYUK, V. V. & Berezhnitskii, L. T. Determination of the ultimate stresses for a plate containing an arcwise crack in tension. Vopr. Mekh. Real. Tverd. Tela, Issue 3, 3-19, 1964.
12. PANASYUK, V. V., Berezhnitskii, L. T. & Kovchik, S. E. (1965). Propagation of an arbitrarily oriented rectilinear crack. Prikl. Mekh., 1, 2, 48-55.
14. V. V. PANASYUK, O. E. Andreikiv, and S. E. Kovchik, Methods for the Evaluation of Crack Resistance of Structural Materials [in Russian], Naukova Dumka, Kiev (1977).
17. Leonov, M. Ya. & PANASYUK, V. V. (1959). Propagation of very small cracks in solid bodies. Prikl. Mekh., 5, 4, 391-401.
18. V. V. PANASYUK, "On the theory of propagation of cracks in deformed brittle bodies," Dop. Akad. Nauk Ukr. RSR, No. 9, 1185-1188, (1960).
19. V. V. PANASYUK, Limiting Equilibrium of Brittle Cracked Bodies [in Russian], Naukova Dumka, Kiev (1968).
23. PANASYUK, V. V. & Savruk, M. P., "Plastic strip model in elastic-plastic problems of fracture mechanics, " Adv. Mech., 15, No. 3. 123-147, 1992.
27. Ostash, O. P. & PANASYUK, V. V. (2003). A unified approach to fatigue macrocrack initiation and propagation. Inter. J. Fatigue, 25, 703-708.
28. Ostash, O. P. V. V PANASYUK, and E.M. Kostyk, "A unified model of initiation and propagation of fatigue macrocracks, " Fiz. Khim. Mekh. Mater., 34, No. 1, 7-21 (1998); 34, No. 3, 55-66 (1998); 35, No. 3. 7-14, 1999.
36. PANASYUK, V. V., Datsyshyn, O. P. & Marchenko, H. P. (1995). To crack propagation theory under rolling contact. Eng. Fract. Mech., 52, 1, 179-191.
37. Datsyshyn, O. P. & PANASYUK, V. V. Pitting of the rolling bodies contact surface. Wear, 251, 1-12, 1347-1355, 2001.
38. I. M. Dmytrakh and V. V. PANASYUK, Influence of Corrosive Media on the Local Fracture of Metals Near Stress Concentrators [in Ukrainian], Karpenko Physicomechanical Institute, Ukrainian National Academy of Sciences, Lviv (1999).
39. V. V. PANASYUK, L. V. Ratych, and I. M. Dmytrakh, "Fatigue crack growth in corrosive environments," Fatigue Fract. Eng. Mech. Struct., 7, No. 1, 1-11, (1984).
4. V. V. PANASYUK, M. P. Savruk, and A. P. Datsyshin, Distributions of Stresses Near Cracks in Plates and Shells [in Russian], Naukova Dumka, Kiev (1976).
15. PANASYUK, V. V. & Savruk, M. P. (1984). Two-dimensional problems of heat conduction and thermoelasticity for cracked bodies. Uspekhi Mekh., 7, 2, 75-115.
17. V. V. PANASYUK and M. P. Savruk, "Integral equation solutions for plane problems of heat conduction and thermoelasticity for cracked solids," in: Proc. of the Internat. Congr. on Future Trends in Applied Mechanics, Athens (1989), pp. 145-174.
29. M. Savruk and O. Matvisiv, "Dynamic problem for a cracked body under the conditions of antiplane deformation," in: V. V. PANASYUK (editor), Fracture Mechanics of Materials and Strength of Structures [in Ukrainian], Karpenko Physicomechanical Institute, Ukrainian National Academy of Sciences, Lviv (2004), pp. 255-260.
30. Vitvitskii, P. M., PANASYUK, V. V. & Yarema, S. Ya. (1973). Plastic strains near cracks and fracture criteria. Probl. Prochn., 2, 3-18.
31. PANASYUK, V. V. & Savruk, M. P. (1992). Model of plastic strips in the elastoplastic problems of fracture mechanics. Fiz.-Khim. Mekh. Mater., 28, 1, 49-68.
34. PANASYUK, V. V., Savruk, M. P. & Danylovych, A. M. (1995). Development of secondary plastic strips near the tip of a tensile crack in a plate. Fiz.-Khim. Mekh. Mater., 31, 2, 7-14.
38. M. Savruk and V. Kravets', "Application of singular integral equations to the solution of two-dimensional elastoplastic problems of fracture mechanics," in: V. V. PANASYUK (editor), Fracture Mechanics of Materials and Strength of Structures [in Ukrainian], Karpenko Physicomechanical Institute, Ukrainian National Academy of Sciences, Lviv (2004), pp. 249-254.
Title Interaction of microcracks with a macrocrack yielded in a narrow strip.
Author Tamuzs, V.; Petrova, V.; Tarasovs, S.
11. PANASYUK, V., Savruk, M. & Datsyshin, A. Stress Distribution near Cracks in Plates and Shells, Naukova Dumka, Kiev, 1976 (in Russian).
25. PANASYUK, V., Savruk, M. & Datsyshin, A. Stress Distribution near Cracks in Plates and Shells, Naukova Dumka, Kiev, 1976 (in Russian).
8. I. I. Bulyk, R. V. Denys, V. V. PANASYUK, et al., "HDDR process and hydrogen-sorption properties of didymium-aluminum -iron boron alloy (Dd1, 3 A11 , Fe79.4 B6 )," Fiz.-Khini. Mekh. Mater., 37, No. 4, 15-20 (2001).
9. V. V. PANASYUK, I. I. Bulyk, and A. M. Trostianchyn, "Peculiarities of the HDDR process in R-Fe-B ferromagnetic alloys (R is mixture of Nd, Pr, Ce, La, Dy and others)," in: Proc. 17th Int. Workshop on Rare Earth Magnets and Their Applications (Newark, Del., Aug. 2002), Newark, Del. (2002), pp. 551-557.
Title The Leonov-PANASYUK-Dugdale model for a crack at the interface of the joint of materials.
Author Bakirov, V.F.; Gol'dshtein, R.V.
8. Leonov, M.Y. & PANASYUK, V.V. (1959). The development of very shallow cracks in a solid. Prikl Mekh., 5, 4, 391-401.
4. PANASYUK, V. V., Andrejkiv, A. E. & Stadnik, M. M. Three-dimensional static crack problems solution (a review). Engng Fract. Mech. 14. 245-260, 1981.
Title A computational model of fatigue fracture of materials.
Title Stress-strain relations in elastoplastic solids with Dugdale-type cracks.
8. PANASYUK, V.V. & Savruk, M.P. (1992). Plastic strip model in elastic-plastic problems of fracture mechanics. Adv. Mech., 15, 3-4, 123-147.
Title Evaluation of corrosion-fatigue strength of welded joints as heterogeneous systems.
Title Deformation fracture criterion for bodies with V-notches under symmetric loading.
Author Savruk, M.P.; Zavodovs'kyi, A.M.; PANASYUK, V.E.; Bida, N.M.
Title Interaction of several dies on an elastic half-space.
7. Andreikiv, A.E. & PANASYUK, V.V. (1971). A system of circular dies on an elastic half-space. Dop. AN Ukr. RSR, Ser. A, 6, 535-536.
Title Specific features of phase transformations in lanthanum-nickel-aluminum alloys under the action of hydrogen.
Author Bulyk, I.I.; PANASYUK, V.V.; Trostyanchyn, A.M.
Title Wedging an orthotropic body by a rectangular wedge of finite length.

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