Papers and Books

  • E.I. Grigolyuk, G.M. Kulikov. Multilayered Reinforced Shells. Analysis of Pneumatic Tires. M.: Mashinostroyenie, 1988, 288 p. (in Russian) (djv file).
  • G.M. Kulikov, A.D. Nakhman. Fourier Method in Equations of Mathematical Physics. M.: Mashinostroyenie, 2000, 156 p. (in Russian).
  • G.M. Kulikov. Application of strong SaS formulation and enhanced DQ method to 3D stress analysis of rectangular plates. European Journal of Mechanics / A Solids, 2020, Vol. 79, P. 1-16.
  • G.M. Kulikov, S.V. Plotnikova. Finite rotation exact geometry solid-shell element for laminated composite structures through extended SaS formulation and 3D analytical integration. International Journal for Numerical Methods in Engineering, 2019, Vol. 119, P. 852-878.
  • G.M. Kulikov, S.V. Plotnikova, M.G. Kulikov. Three-dimensional vibration analysis of simply supported laminated cylindrical shells and panels by a strong SaS formulation. ZAMM - Journal of Applied Mathematics and Mechanics, 2019, Vol. 99, N 1, P. 1-17 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Analysis of the second Piola-Kirchhoff stress in nonlinear thick and thin structures using exact geometry SaS solid-shell elements. International Journal for Numerical Methods in Engineering. 2019, Vol. 117, P. 498-522.
  • G. Li., E. Carrera, M. Cinefra, A.G. de Miguel, G.M. Kulikov, A. Pagani, E. Zappino. Evaluation of shear and membrane locking in refined hierarchical shell finite elements for laminated structures. Advanced Modeling and Simulation in Engineering Sciences. 2019, Vol. 6, N 1, P. 1-24 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova, E. Carrera. A robust, four-node, quadrilateral element for stress analysis of functionally graded plates through higher-order theories. Mechanics of Advanced Materials and Structures. 2018, Vol. 25, P. 1383-1402 (pdf file).
  • E. Carrera, S. Valvano, G.M. Kulikov. Multilayered plate elements with node-dependent kinematics for electro-mechanical problems. International Journal of Smart and Nano Materials. 2018, Vol. 9, N 4, P. 279-317 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Exact geometry SaS solid-shell element for 3D stress analysis of FGM piezoelectric structures. Curved and Layered Structures. 2018, Vol. 5, P. 116-135 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova, E. Carrera. Hybrid-mixed solid-shell element for stress analysis of laminated piezoelectric shells through higher-order theories. Advanced Structured Materials. 2018, Vol. 81, P. 45-68 (pdf file).
  • E. Carrera, S. Valvano, G.M. Kulikov. Electro-mechanical analysis of composite and sandwich multilayered structures by shell elements with node-dependent kinematics. International Journal of Smart and Nano Materials. 2018, Vol. 9, N 1, P. 1-33 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Benchmark solutions for the free vibration of layered piezoelectric plates based on a variational formulation. Journal of Intelligent Material Systems and Structures. 2017, Vol. 28, N 19, P. 2688-2704 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova, M.G. Kulikov. Strong SaS formulation for free and forced vibrations of laminated composite plates. Composite Structures. 2017, Vol. 180, P. 286-297 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Strong sampling surfaces formulation for layered shells. International Journal of Solids and Structures. 2017, Vol. 121, P. 75-85 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Strong sampling surfaces formulation for laminated composite plates. Composite Structures. 2017, Vol. 172, P. 73-82 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. An analytical approach to three-dimensional coupled thermoelectroelastic analysis of functionally graded piezoelectric plates. Journal of Intelligent Material Systems and Structures. 2017, Vol. 28, N 4, P. 435-450 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Three-dimensional solution of the free vibration problem for metal-ceramic shells using the method of sampling surfaces. Mechanics of Composite Materials. 2017, Vol. 53, N 1, P. 31-44 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Assessment of the sampling surfaces formulation for thermoelectroelastic analysis of layered and functionally graded piezoelectric shells. Mechanics of Advanced Materials and Structures. 2017, Vol. 24, P. 392-409 (pdf file).
  • G.M. Kulikov, E. Carrera, S.V. Plotnikova. Hybrid-mixed quadrilateral element for laminated plates composed of functionally graded materials. Advanced Materials & Technologies. 2017, N 1, P. 44-55 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. A hybrid-mixed four-node quadrilateral plate element based on sampling surfaces method for 3D stress analysis. International Journal for Numerical Methods in Engineering. 2016, Vol. 108, N 1, P. 26-54 (pdf file).
  • E. Carrera, M. Cinefra, G. Li, G.M. Kulikov. MITC9 shell finite elements with miscellaneous through-the-thickness functions for the analysis of laminated structures. Composite Structures. 2016, Vol. 154, P. 360-373 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova, M.G. Kulikov, P.V. Monastyrev. Three-dimensional vibration analysis of layered and functionally graded plates through sampling surfaces formulation. Composite Structures. 2016, Vol. 152, P. 349-361 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova, A.A. Mamontov. Sampling surfaces formulation for thermoelastic analysis of laminated functionally graded shells. Meccanica. 2016, Vol. 51, N 8, P. 1913-1929 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Hybrid-mixed ANS finite elements for stress analysis of laminated composite structures: Sampling surfaces plate formulation. Computer Methods in Applied Mechanics and Engineering. 2016, Vol. 303, P. 374-399 (pdf file).
  • G.M. Kulikov, A.A. Mamontov, S.V. Plotnikova, S.A. Mamontov. Exact geometry solid-shell element based on a sampling surfaces technique for 3D stress analysis of doubly-curved composite shells. Curved and Layered Structures. 2016, Vol. 3, P. 1-16 (pdf file).
  • G.M. Kulikov, A.A. Mamontov, S.V. Plotnikova, M.G. Kulikov, S.A. Mamontov. Sampling surfaces formulation for functionally graded and laminated composite shells. Advanced Materials & Technologies. 2016, N 1, P. 61-66 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Three-dimensional analysis of metal-ceramic shells by the method of sampling surfaces. Mechanics of Composite Materials. 2015, Vol. 51, N 4, P. 455-464 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. The use of 9-parameter shell theory for development of exact geometry 12-node quadrilateral piezoelectric laminated solid-shell elements. Mechanics of Advanced Materials and Structures. 2015, Vol. 22, P. 490-502 (pdf file).
  • G.M. Kulikov, A.A. Mamontov, S.V. Plotnikova. Coupled thermoelectroelastic stress analysis of piezoelectric shells. Composite Structures. 2015, Vol. 124, P. 65-76 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. A sampling surfaces method and its implementation for 3D thermal stress analysis of functionally graded plates. Composite Structures. 2015, Vol. 120, P. 315-325 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Exact 3D thermoelectroelastic analysis of piezoelectric plates through a sampling surfaces method. Mechanics of Advanced Materials and Structures. 2015, Vol. 22, P. 33-43 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Three-dimensional thermal stress analysis of laminated composite plates with general layups by a sampling surfaces method. European Journal of Mechanics A/Solids. 2015, Vol. 49, P. 214-226 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Three-dimensional exact analysis of functionally graded laminated composite plates. Advanced Structured Materials. 2015, Vol. 45, P. 223-241 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Exact electroelastic analysis of functionally graded piezoelectric shells. International Journal of Solids and Structures. 2014, Vol. 51, N 1, P. 13-25 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Heat conduction analysis of laminated shells by a sampling surfaces method. Mechanics Research Communications. 2014, Vol. 55, P. 59-65 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Analytical method for solving three-dimensional thermoelasticity problems for composite shells. Journal of Machinery Manufacture and Reliability. 2014, Vol. 43, N 2, P. 132-139 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Solution of three-dimensional problems for thick elastic shells by the method of reference surfaces. Mechanics of Solids. 2014, Vol. 49, N 4, P. 403-412 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. 3D exact thermoelastic analysis of laminated composite shells via sampling surfaces method. Composite Structures. 2014, V. 115, P. 120-130 (pdf file).
  • G.M. Kulikov, A.V. Erofeev. Exact solution for functionally graded piezoelectric cylindrical shells. Trans. TSTU. 2013, Vol. 19, N 2, P. 390-401 (pdf file).
  • G.M. Kulikov, A.A. Mamontov. Three-dimensional thermoelastic analysis of laminated anisotropic plates. Trans. TSTU. 2013, Vol. 19, N 4, P. 853-863 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Three-dimensional exact analysis of piezoelectric laminated plates via a sampling surfaces method. International Journal of Solids and Structures. 2013, Vol. 50, P. 1916-1929 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. A sampling surfaces method and its application to three-dimensional exact solutions for piezoelectric laminated shells. International Journal of Solids and Structures. 2013, Vol. 50, P. 1930-1943 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Advanced formulation for laminated composite shells: 3D stress analysis and rigid-body motions. Composite Structures. 2013, Vol. 95, P. 236-246 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. A new approach to three-dimensional exact solutions for functionally graded piezoelectric laminated plates. Composite Structures. 2013, Vol. 106, P. 33-46 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Three-dimensional exact analysis of laminated piezoelectric plates and shells. Advanced Materials Research. 2013, Vol. 745, P. 1-12 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. A method of solving three-dimensional problems of elasticity for laminated composite plates. Mechanics of Composite Materials. 2012, Vol. 48, N 1, P. 15-26 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Cylindrical bending of angle-ply composite plates. Trans. TSTU. 2012, Vol. 18, N 2, P. 432-440 (pdf file).
  • G.M. Kulikov, A.A. Mamontov, S.V. Plotnikova, A.V. Erofeev. Laminated composite shell in cylindrical bending. Trans. TSTU. 2012, Vol. 18, N 3, P. 672-682 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. On the use of sampling surfaces method for solution of 3D elasticity problems for thick shells. ZAMM - Journal of Applied Mathematics and Mechanics. 2012, Vol. 92, N 12, P. 910-920 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Exact 3D stress analysis of laminated composite plates by sampling surfaces method. Composite Structures. 2012, Vol. 94, N 11-12, P. 3654-3663 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Solution of static problems for a three-dimensional elastic shell. Doklady Physics. 2011, Vol. 56, N 8, P. 448-451 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Non-linear exact geometry 12-node solid-shell element with three translational degrees of freedom per node. International Journal for Numerical Methods in Engineering. 2011, Vol. 88, N 13, P. 1363-1389 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Exact geometry piezoelectric solid-shell element based on the 7-parameter model. Mechanics of Advanced Materials and Structures. 2011, Vol. 18, N 2, P. 133-146 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. On the use of a new concept of sampling surfaces in a shell theory. Advanced Structured Materials. 2011, Vol. 15, P. 715-726 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Finite rotation piezoelectric exact geometry solid-shell element with nine degrees of freedom per node. Computers, Materials & Continua. 2011, Vol. 23, N 3, P. 233-264 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. A family of ANS four-node exact geometry shell elements in general convected curvilinear coordinates. International Journal for Numerical Methods in Engineering. 2010, Vol. 83, N 10, P. 1376-1406 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Solution of a coupled problem of thermopiezoelectricity based on a geometrically exact shell element. Mechanics of Composite Materials. 2010, Vol. 46, N 4, P. 349-364 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Contact interaction of composite shells, subjected to follower loads, with a rigid convex foundation. Mechanics of Composite Materials. 2010, Vol. 46, N 1, P. 43-56 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Calculation of composite structures subjected to follower loads by using a geometrically exact shell element. Mechanics of Composite Materials. 2009, Vol. 45, N 6, P. 545-556 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Non-linear geometrically exact solid-shell element under follower loads. Shell Structures: Theory and Applications. Vol. 2. Eds. W. Pietraszkiewicz, I. Kreja. New York: CRC Press, Taylor & Francis, 2009, P. 257-260 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Hybrid solid-plate quadrilaterals. An assessment and new developments. Trans TSTU. 2008, Vol. 14, N 4, P. 928-938 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Finite rotation geometrically exact four-node solid-shell element with seven displacement degrees of freedom. Computer Modeling in Engineering & Sciences. 2008, Vol. 28, N 1, P. 15-38 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Geometrically exact four-node piezoelectric solid-shell element. Mechanics of Advanced Materials and Structures. 2008, Vol. 15, N 3-4, P. 199-207 (pdf file).
  • G.M. Kulikov, E. Carrera, S.V. Plotnikova, S. Brischetto. Geometrically exact assumed stress-strain four-node element based on the 9-parameter shell model. International Conference on Computational & Experimental Engineering and Sciences Online Version. 2008, Vol. 5, N 3, P. 187-192 (pdf file).
  • G.M. Kulikov, E. Carrera. Finite deformation higher-order shell models and rigid-body motions. International Journal of Solids and Structures. 2008, Vol. 45, N 11-12, P. 3153-3172 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Non-linear geometrically exact assumed stress-strain four-node solid-shell element with high coarse-mesh accuracy. Finite Elements in Analysis and Design. 2007, Vol. 43, N 6-7, P. 425-443 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Non-linear strain-displacement equations exactly representing large rigid-body motions. Part III. Analysis of TM shells with constraints // Computer Methods in Applied Mechanics and Engineering. 2007, Vol. 196, N 7, P. 1203-1215 (pdf file).
  • G.M. Kulikov. On the first-order seven-parameter plate theory. Trans. TSTU. 2007, Vol. 13, N 2B, P. 518-528 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Geometrically exact assumed stress-strain multilayered solid-shell elements based on the 3D analytical integration. Computers & Structures. 2006, Vol. 84, N 19-20, P. 1275-1287 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Non-linear strain-displacement equations exactly representing large rigid-body motions. Part II. Enhanced finite element technique. Computer Methods in Applied Mechanics and Engineering. 2006, Vol. 195, N 19-22, P. 2209-2230 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Assumed stress-strain quadrilateral plate elements based on analytical and numerical integration. Trans. TSTU. 2006, Vol. 12, N 1, P. 107-121 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Equivalent single-layer and layer-wise shell theories and rigid-body motions - Part I: Foundations. Mechanics of Advanced Materials and Structures. 2005, Vol. 12, P. 275-283 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Equivalent single-layer and layer-wise shell theories and rigid-body motions - Part II: Computational aspects. Mechanics of Advanced Materials and Structures. 2005, Vol. 12, P. 331-340 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. On the use of 6-parameter multilayered shell models in structural mechanics. Trans. TSTU. 2004, Vol. 10, N 4, P. 1042-1052 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov, S.V. Plotnikova. Contact problem for pneumatic tire interacting with rigid foundation. Mechanics of Composite Materials. 2004, Vol. 40, N 5, P. 427-436 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov, S.V. Plotnikova. Contact problem for pneumatic tire interacting with rigid base. Problemy Mashinostraeniya i Nadezhnos'ti Mashin. 2004, N 4, P. 55-63.
  • G.M. Kulikov. Strain-displacement relationships that exactly represent large rigid displacements of a shell. Mechanics of Solids. 2004, Vol. 39, N 5, P. 105-113 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Non-conventional non-linear two-node hybrid stress-strain curved beam elements. Finite Elements in Analysis and Design. 2004, Vol. 40, N 11, P. 1333-1359 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Finite deformation plate theory and large rigid-body motions. International Journal of Non-Linear Mechanics. 2004, Vol. 39, N 7, P. 1093-1109 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. The contact problem for a geometrically non-linear Timoshenko-type shell. Journal of Applied Mathematics and Mechanics. 2003, Vol. 67, N 6, P. 825-836 (pdf file).
  • G.M. Kulikov. Large rigid-body motions and strain-displacement relationships of the layer-wise shell theory. Trans. TSTU. 2003, Vol. 9, N 4, P. 674-682 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Non-linear strain-displacement equations exactly representing large rigid-body motions. Part I. Timoshenko-Mindlin shell theory. Computer Methods in Applied Mechanics and Engineering. 2003, Vol. 192, N 7-8, P. 851-875 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Investigation of locally loaded multilayered shells by mixed finite-element method. 2. Geometrically nonlinear statement. Mechanics of Composite Materials. 2002, Vol. 38, N 6, P. 539-546 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Investigation of locally loaded multilayered shells by mixed finite-element method. 1. Geometrically linear statement. Mechanics of Composite Materials. 2002, Vol. 38, N 5, P. 397-406 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Efficient mixed Timoshenko-Mindlin shell elements. International Journal for Numerical Methods in Engineering. 2002, Vol. 55, N 10, P. 1167-1183 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov. The shear correction factor in the geometrically nonlinear theory of Timoshenko shells. Doklady Physics. 2002, Vol. 47, N 2, P. 145-147 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Simple and effective elements based upon Timoshenko-Mindlin shell theory. Computer Methods in Applied Mechanics and Engineering. 2002, Vol. 191, N 11-12, P. 1173-1187 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov. On the shear correction factor in the Timoshenko-type shell theory. Doklady Physics. 2001, Vol. 46, N 11, P. 797-799 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Finite element formulation of straight composite beams undergoing finite rotations. Trans. TSTU. 2001, Vol. 7, N 4, P. 617-633 (pdf file).
  • G.M. Kulikov. Analysis of initially stressed multilayered shells. International Journal of Solids and Structures. 2001, Vol. 38, N 26-27, P. 4535-4555 (pdf file).
  • G.M. Kulikov. Non-linear analysis of multilayered shells under initial stress. International Journal of Non-Linear Mechanics. 2001, Vol. 36, N 2, P. 323-334 (pdf file).
  • G.M. Kulikov. Refined global approximation theory of multilayered plates and shells, Journal of Engineering Mechanics. 2001, Vol. 127, N 2, P. 119-125 (pdf file).
  • G.M. Kulikov, F. Böhm, A. Duda, R. Wille. Zur inneren Mechanik des Radialreifens. Teil 1.: Geschichtete Kompositschale mit globalem Verschiebungsansatz für das Gesamtlaminat. Technische Mechanik. 2000, Bd. 20, N 1, S. 1-12 (pdf file).
  • G.M. Kulikov G.M., F. Böhm, A. Duda, R. Wille, S.V. Plotnikova. Zur inneren Mechanik des Radialreifens. Teil 2.: Geschichtete Kompositschale mit diskreten Verschiebungsansätzen für die einzelnen Schichten. Technische Mechanik. 2000, Bd. 20, N 1, S. 81-90 (pdf file).
  • G.M. Kulikov, S.V. Plotnikova. Comparative analysis of two algorithms for numerical solution of nonlinear static problems for multilayered anisotropic shells of revolution. 2. Account of transverse compression. Mechanics of Composite Materials. 1999, Vol. 35, N 4, P. 293-300.
  • G.M. Kulikov, S.V. Plotnikova. Comparative analysis of two algorithms for numerical solution of nonlinear static problems for multilayered anisotropic shells of revolution. 1. Account of transverse shear. Mechanics of Composite Materials. 1999, Vol. 35, N 3, P. 241-248.
  • G.M. Kulikov. Variational equation for the nonlinear multilayered anisotropic shell of variable stiffness. Trans. TSTU. 1997, Vol. 3, N 1-2, P. 119-125.
  • G.M. Kulikov. Computational models for multilayered composite shells with application to tires. Tire Science and Technology. 1996, Vol. 24, N 1, P. 11-38 (pdf file).
  • G.M. Kulikov. Mixed variational equation for geometrically nonlinear multilayered anisotropic shell of variable thickness. Trans. TSTU. 1995, Vol. 1, N 1-2, P. 129-135.
  • G.M. Kulikov. Thermoelasticity of flexible multilayer anisotropic shells. Mechanics of Solids. 1994, Vol. 29, N 2, P. 27-35 (pdf file).
  • G.M. Kulikov, S.V. Mishchenko. Thermally forced loading of multilayered anisotropic shells. Mechanics of Composite Materials. 1993, Vol. 29, N 2, P. 143-152 (pdf file).
  • G.M. Kulikov. Nonaxisymmetric deformation of tangentially loaded multilayered anisotropic shells of revolution. Mechanics of Composite Materials. 1993, Vol. 28, N 5, P. 409-413.
  • E.I. Grigolyuk, G.M. Kulikov. Axisymmetric deformation of multilayered anisotropic shells of revolution subjected to tangential loads. Mechanics of Composite Materials. 1993, Vol. 28, N 4, P. 334-340.
  • E.I. Grigolyuk, G.M. Kulikov. Local loading of rubber-cord shells of revolution. Mechanics of Composite Materials. 1992, Vol. 27, N 4, P. 436-441.
  • G.M. Kulikov. Nonaxisymmetric stress-strain state of multilayer anisotropic shells of revolution. Soviet Applied Mechanics. 1991, Vol. 26, N 11, P. 1077-1080.
  • G.M. Kulikov. Design of pneumatic tires on the basis of a generalized broken-line hypothesis. Strength of Materials. 1990, Vol. 22, N 2, P. 272-277.
  • G.M. Kulikov. Nonaxisymmetric loading of a prestressed multilayered reinforced shell. Mechanics of Composite Materials. 1990, Vol. 26, N 2, P. 254-258.
  • E.I. Grigolyuk, G.M. Kulikov. Mechanics of structures made of rubber and cord materials. Mechanics of Composite Materials. 1990, Vol. 25, N 4, P. 500-509.
  • E.I. Grigolyuk, G.M. Kulikov, P.Ya. Nosatenko. Comparative analysis of two approaches to more accurate calculation of laminated shells made of composite materials. Mechanics of Composite Materials. 1989, Vol. 24, N 6, P. 804-810.
  • E.I. Grigolyuk, G.M. Kulikov. Generalized model of the mechanics of thin-walled structures made of composite materials. Mechanics of Composite Materials. 1989, Vol. 24, N 4, P. 537-543 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov. General direction of development of the theory of multilayered shells. Mechanics of Composite Materials. 1988, Vol. 24, N 2, P. 231-241 (pdf file).
  • G.M. Kulikov. Stressed-strained state of shells made of layered composites. Journal of Applied Mechanics and Technical Physics. 1988, Vol. 29, N 5, P. 745-750.
  • G.M. Kulikov. Influence of anisotropy on the stress state of multilayer reinforced shells. Soviet Applied Mechanics. 1987, Vol. 22, N 12, P. 1166-1170.
  • E.I. Grigolyuk, G.M. Kulikov. Effect of shear-stress nonuniformity in modern tires. Mechanics of Composite Materials. 1987, Vol. 22, N 5, P. 607-613 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov. Theory and numerical solution of problems of the statics of multilayered reinforced shells. Mechanics of Composite Materials. 1987, Vol. 22, N 4, P. 450-457 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov. A variant of the nonlinear theory of elastic multilayered flat shells. Mechanics of Composite Materials. 1986, Vol. 21, N 5, P. 587-593.
  • E.I. Grigolyuk, G.M. Kulikov, L.G. Korneichuk, P.Ya. Nosatenko. Stress-strain state of modern tires. Mechanics of Composite Materials. 1984, Vol. 20, N 2, P. 227-238.
  • E.I. Grigolyuk, G.M. Kulikov. Design of radial tires on the basis of Timoshenko's generalized theory. Mechanics of Solids. 1984, Vol. 19, N 4, P. 162-170.
  • E.I. Grigolyuk, G.M. Kulikov. Toward a theory of elastic laminated anisotropic shells. Soviet Physics Doklady. 1984, Vol. 29, N 4, P. 344-345 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov. Axisymmetric deformation of anisotropic multilayered shells of revolution of intricate shapes. Mechanics of Composite Materials. 1982, Vol. 17, N 4, P. 437-445 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov. Numerical solution of problems involving the statics of geometrically nonlinear anisotropic multilayered shells of revolution. Mechanics of Composite Materials. 1981, Vol. 17, N 3, P. 294-302 (pdf file).
  • E.I. Grigolyuk, G.M. Kulikov. Approximate analysis of nonlinear transversely isotropic three-layered plates. Mechanics of Composite Materials. 1980, Vol. 16, N 2, P. 202-206.
  • E.I. Grigolyuk, G.M. Kulikov G.M. Approximate analysis of anisotropic three-layered plates of finite deflection. Mechanics of Composite Materials. 1980, Vol. 16, N 1, P. 34-39.
  • G.M. Kulikov. On the theory of multilayer shallow shells of finite deflection. Mechanics of Solids. 1979, Vol. 14, N 3, P. 167-170 (pdf file).