Professor
Tarun Kant
Papers in
Refereed Journals
1. Kant, T. and Setlur,
A.V. (1973), Computer analysis of clamped-clamped and clamped supported
cylindrical shells, Journal of The
Aeronautical Society of India 25,
47-55. RECIPIENT of BURMAH SHELL PRIZE Award
2. Ramesh, C.K., Kant, T. and Jadhav,
V.B. (1974), Elastic analysis of cylindrical pressure vessels with various end
closures, International Journal of
Pressure Vessels and Piping 2,
143-154.
3. Kant, T. (1978), Stress analysis of pressure
vessels, Chemical Age of India 29, 319-322.
4. Kant, T. and Ramesh, C.K. (1981), Numerical
integration of linear boundary value problems in solid mechanics by
segmentation method, International
Journal for Numerical Methods in Engineering 17, 1233-1256.
5. Kant, T. (1981), Numerical analysis of elastic
plates with two opposite simply supported ends by segmentation method, Computers and Structures 14, 195-203.
6. Kant, T. (1982), Numerical analysis of thick
plates, Computer Methods in Applied
Mechanics and Engineering 31,
1-18.
7. Kant, T., Owen, D.R.J. and Zienkiewicz,
O.C. (1982), A refined higher-order Co
plate bending element, Computers and
Structures 15, 177-183.
8. Kant, T. and Hinton, E. (1983), Mindlin plate analysis by segmentation method, ASCE Journal of Engineering Mechanics 109, 537-556.
9. Kant, T. and Kulkarni, P.B. (1986), A Co
continuous linear beam/bilinear plate flexure element, Computers and Structures 22,
413-425.
10.
Pandya, B.N. and Kant, T. (1987), A
consistent refined theory for flexure of a symmetric laminate, Mechanics Research Communications 14, 107-113.
11.
Pandya, B.N. and Kant, T. (1988), A refined higher-order generally
orthotropic C0 plate bending element, Computers and Structures 28,
119-133.
12.
Pandya, B.N. and Kant, T. (1988), Flexure analysis of laminated
composites using refined higher-order C0 plate bending elements, Computer Methods in Applied Mechanics and
Engineering 66, 173-198.
13.
Kant, T. and Pandya, B.N. (1988), A simple finite element formulation
of a higher-order theory for unsymmetrically laminated composite plates, Composite Structures 9, 215-246.
14.
Kant, T., Ravichandran, R.V., Pandya, B.N.
and Mallikarjuna (1988), Finite element transient
dynamic analysis of isotropic and fibre-reinforced
composite plates using a higher-order theory, Composite Structures 9(4),
319-342.
15.
Pandya, B.N. and Kant, T. (1988), Finite element stress analysis of
laminated composite plates using a higher-order displacement model, Composite Science and Technology 32,137-155.
16.
Pandya, B.N. and Kant, T. (1988), Higher-order shear deformable
theories for flexure of sandwich plates : finite
element evaluations, International
Journal of Solids and Structures 24(12),
1267-1286.
17.
Kant, T. and Gupta, A. (1988), A finite element model for a
higher-order shear-deformable beam theory, Journal
of Sound and Vibration 125(2),
193-202.
18.
Mallikarjuna and Kant, T. (1988), Dynamics of laminated
composite plates with a higher-order theory and finite element discretization, Journal of Sound and Vibration 126(3), 463-475.
19.
Kant, T. and Manjunatha, B.S. (1988), An unsymmetric FRC laminate C0 finite element model
with 12 degrees of freedom per node, Engineering
Computations 5(4), 300-308.
20.
Mallikarjuna and Kant, T. (1989), Free vibration of
symmetrically laminated plates using a higher-order theory and finite element
technique, International Journal for
Numerical Methods in Engineering 28(8),
1875-1889.
21.
Kant, T. and Mallikarjuna (1989), A
higher-order theory for free vibration of unsymmetrically laminated composite
and sandwich plates - finite element evaluations, Computers and Structures 32(5),
1125-1132.
22.
Kant, T. and Mallikarjuna (1989), Vibrations
of unsymmetrically laminated plates analyzed by using a higher-order theory
with a C0 finite element formulation, Journal of Sound and Vibration 134(1),
1-16.
23.
Mallikarjuna and Kant, T. (1989), Finite element
formulation of a higher-order theory for dynamic response of laminated
composite plates, Engineering
Computations 6(3), 198-208.
24.
Kant, T. and Mallikarjuna (1989), Transient
dynamics of composite sandwich plates using 4-, 8-, 9-noded isoparametric
quadrilateral elements, Finite Elements
in Analysis and Design 6,
307-318.
25.
Kant, T. and Menon, M.P. (1989), Higher-order theories for composite
and sandwich cylindrical shells with C0 finite elements, Computers and Structures 33(5), 1191-1204.
26.
Kant, T. and Manjunatha, B.S. (1989),
Refined theories for composite and sandwich beams with C0 finite
elements, Computers and Structures 33(3), 755-764.
27.
Butalia, T.S., Kant, T. and Dixit, V.D. (1990),
Performance of Heterosis element for bending of skew
rhombic plates, Computers and Structures 34(1),
23-50.
28.
Singh, R.K., Kant, T. and Kakodkar, A.
(1990), Efficient partitioning schemes for fluid-structure interaction
problems, Engineering Computations 7(2), 101-115.
29.
Kant, T. and Manjunatha, B.S. (1990),
Higher-order theories for symmetric and unsymmetric fibre reinforced composite beams with C0 finite
elements, Finite Elements in Analysis and
Design 6, 303-320.
30.
Kant, T. and Patel, S. (1990), Transient/pseudo-transient finite
element small/large deformation analysis of two-dimensional problems, Computers and Structures 36(3), 421-427.
31.
Kant, T., Varaiya, J.H. and Arora, C.P.
(1990), Finite element transient analysis of composite and sandwich plates
based on a refined theory and implicit time integration schemes, Computers and Structures 36(3), 401-420.
32.
Mallikarjuna and Kant, T. (1990), Analysis of anisotropic
composite/sandwich shells using a new displacement model with the
super-parametric element, Journal of
Structural Engineering 17(3),
91-100.
33.
Mallikarjuna and Kant, T. (1990), Finite element transient
response of composite and sandwich plates with a refined higher-order theory, ASME J. Applied Mechanics 57(4), 1084-1086.
34.
Kant, T. and Patil, H.S. (1991), Buckling
loads of sandwich columns with a higher-order theory, J. Reinforced Plastics and Composites 10(1), 102-109.
35.
Kant, T. and Menon, M.P. (1991), Estimation of interlaminar
stresses in fibre reinforced composite cylindrical
shells, Computers and Structures 38(2), 131-147.
36.
Singh, R.K., Kant, T. and Kakodkar, A.
(1991), Coupled shell-fluid interaction problems with degenerate shell and three dimensional fluid elements, Computers and Structures 38(5/6),
515-528.
37.
Kant, T. and Mallikarjuna (1991), Nonlinear
dynamics of laminated plates with a higher-order theory and C0
finite elements, International Journal of
Non-Linear Mechanics 26(3/4),
335-343.
38.
Kant, T. and Marur, S.R. (1991), A
comparative study of C1 and C0 elements for linear and
nonlinear transient dynamics of building frames, Computers and Structures 40(3),
659-676.
39.
Singh, R.K., Kant, T. and Kakodkar, A.
(1991), Three-dimensional transient analysis of a single submerged cylindrical
shell, Engineering Computations 8(3), 195-213.
40.
Mallikarjuna and Kant, T. (1991), Dynamics of fibre reinforced unsymmetrically laminated
composite-sandwich plates using a refined theory with C0 finite
elements, Journal of Structural
Engineering 18(3), 89-98.
41.
Mallikarjuna and Kant, T. (1992), A
general fibre reinforced composite shell element
based on a refined shear deformation theory, Computers and Structures 42(3),
381-388.
42.
Singh, R.K., Kant, T. and Kakodkar, A.
(1992), Three-dimensional transient analysis of two coupled submerged
cylindrical shells, Engineering
Computations 9, 39-48.
43.
Mallikarjuna, Kant, T. and Fafard,
M. (1992), Transient response of isotropic, orthotropic and anisotropic
composite-sandwich shells with the superparametric
element, Finite Elements in Analysis and
Design 12, 63- 73.
44.
Manjunatha, B.S. and Kant, T. (1992), A comparison of 9
and 16 node quadrilateral elements based on higher-order laminate theories for
estimation of transverse stresses, J.
Reinforced Plastics and Composites 11,
968-1002.
45.
Kant, T. and Kommineni, J.R. (1992),
Geometrically non-linear analysis of doubly curved laminated and sandwich fibre reinforced composite shells with a higher order
theory and C0 finite elements, Journal
of Reinforced Plastics and Composites 11,
1048-1076.
46.
Kant, T., Arora, C.P. and Varaiya, J.H.
(1992), Finite element transient analysis of composite and sandwich plates
based on a refined theory and mode superposition method, Composite Structures 22,
109-120.
47.
Kant, T. and Kommineni, J.R. (1992), C0
finite element geometrically nonlinear analysis of fibre
reinforced composite and sandwich laminates based on a higher-order theory, Computers and Structures 45(3), 511-520.
48.
Mallikarjuna and Kant, T. (1992), Effect of
cross-sectional warping of anisotropic sandwich laminates due to dynamic loads
using a refined theory and C0 finite elements, International Journal for Numerical Methods in Engineering 35(10), 2031-2047.
49.
Kant, T. and Kommineni, J.R. (1993),
Pseudo-transient large-deflection elastic analysis of fibre
reinforced composite plates, Engineering
Computations 10, 159-173.
50.
Manjunatha, B.S. and Kant, T. (1993), New
theories for symmetric/ unsymmetric composite and
sandwich beams with C0 finite elements, Composite Structures 23(1),
61-73.
51.
Manjunatha, B.S. and Kant, T. (1993), Different
numerical techniques for the estimation of multiaxial stresses in symmetric/ unsymmetric composite and sandwich beams with refined
theories, Journal of Reinforced Plastics
and Composites 12, 2-37.
52.
Kommineni, J.R. and Kant, T. (1993), Pseudo-transient
analysis of composite shells including geometric and material non-linearities, Journal
of Reinforced Plastics and Composites 12,
101-126.
53.
Kant, T. and Menon, M.P. (1993), A finite element-difference
computational model for stress analysis of layered composite cylindrical
shells, Finite Elements in Analysis and
Design 14, 55-71.
54.
Kommineni, J.R. and Kant, T. (1993), Geometrically
non-linear transient C0 finite element analysis of composite and
sandwich plates with a refined theory, Structural
Engineering and Mechanics 1(1),
87-102.
55.
Kommineni, J.R. and Kant, T. (1993), Large
deflection elastic and in-elastic transient analyses of composite and sandwich
plates with a refined theory, Journal of
Reinforced Plastics and Composites 12(11),
1150-1170.
56.
Manjunatha, B.S. and Kant, T. (1993), On
evaluation of transverse stresses in layered symmetric composite and sandwich
laminates under flexure, Engineering
Computations 10(6), 499-518.
57.
Mallikarjuna and Kant, T. (1993), A
critical review and some results of recently developed refined theories of fibre-reinforced laminated composites and sandwiches, Composite Structures 24, 293-312.
58.
Kant, T. and Kommineni, J.R. (1994), Large
deflection inelastic pseudo-transient analysis of laminated composite plates, International Journal for Numerical Methods
in Engineering 37, 37-48.
59.
Kant, T. and Kommineni, J.R. (1994),
Geometrically non-linear analysis of symmetrically laminated composite and
sandwich shells with a higher order theory and C0 finite elements, Composite Structures 27, 403-418.
60.
Kant, T. and Khare, R.K. (1994), Finite
Element thermal stress analysis of composite laminates using a higher-order
theory, Journal of Thermal Stresses 17, 229-255.
61.
Kant, T. and Kommineni, J.R. (1994), Large
amplitude free vibration analysis of cross-ply composite and sandwich laminates
with a refined theory C0 finite elements, Computers and Structures 50(1),
123-134.
62.
Kant, T., Kumar, S. and Singh, U.P. (1994), Shell dynamics with
three-dimensional degenerate finite elements, Computers and Structures 50(1),
135-146.
63.
Kant, T. and Kommineni, J.R. (1994),
Nonlinear analysis of angle-ply composite and sandwich laminates, ASCE Journal of Aerospace Engineering 7(3), 342-352.
64.
Kant, T. and Manjunatha, B.S. (1994), On accurate estimation of transverse stresses in multilayer
laminates, Computers and Structures 50(3), 351- 365.
65.
Marur, S.R. and Kant, T. (1994), A stress
correction procedure for the analysis of inelastic frames under transient
dynamic loads, Computers and Structures 50(5), 603-613.
66.
Marur, S.R. and Kant, T. (1994), A
modified form of the central difference predictor scheme for damped nonlinear
systems, Computers and Structures 50(5), 615-618.
67.
Kant, T. and Kommineni, J.R. (1994), Geometrically nonlinear pseudo-transient analysis of
laminated composite shells, Journal of
Structural Engineering 21(1),
37-48.
68.
Kant, T. and Kommineni, J.R. (1994),
Geometrically non-linear transient analysis of laminated composite and sandwich
shells with a refined theory and C0 finite elements, Computers and Structures 52(6), 1243-1259.
69.
Kommineni, J.R. and Kant. (1995), Pseudo transient
large deflection analysis of composite and sandwich shells with a refined
theory, Computer Methods in Applied
Mechanics and Engineering 123,
1-13.
70.
Marur, S.R. and Kant, T. (1996), Free vibration
analysis of fiber reinforced composite beams using higher order theories and
finite element modelling, Journal of
Sound and Vibration 194(3),
337-351.
71.
Marur, S.R. and Kant, T. (1997), On
the performance of higher-order theories for transient dynamic analysis of
sandwich and composite beams, Computers
and Structures 65(5), 741-759.
72.
Kant, T. and Khare, R.K. (1997), A
higher-order facet quadrilateral composite shell element, International Journal for Numerical Methods in Engineering 40, 4477-4499.
73.
Kant, T., Marur, S.R. and Rao, G.S. (1998),
Analytical solution to the dynamic analysis of laminated beams using higher
order refined theory, Composite
Structures 40(1), 1-9.
74.
Goswami, S. and Kant, T. (1998), Shape control of
intelligent composite stiffened structures using piezoelectric materials-A
finite element approach, Journal of
Reinforced Plastics and Composites 17(5),
446-461.
75.
Marur, S.R. and Kant, T. (1998), A
higher order finite element model for the vibration analysis of laminated
beams, ASME Journal of Vibration and
Acoustics 120(3), 822-824.
76.
Marur, S.R. and Kant, T. (1998), Transient dynamics
of laminated beams: an evaluation with a higher-order theory, Composite Structures 41(1),1-11.
77.
Babu, C.S. and Kant, T. (1998), Enhanced
elastic buckling loads of composite plates with tailored thermal residual
stresses, ASME J. Appl. Mech. 65(4), 1070-1071.
78.
Mukherjee, A., Ramana, V.P.V., Kant, T.,
Dutta, P.K. and Desai, Y.M. (1998), Behavior of concrete columns confined by
fiber composites, ASCE J. Structural
Engineering 124(9), 1094-1095.
79.
Goswami, S. and Kant, T. (1998), Active vibration
control of intelligent stiffened laminates using smart piezoelectric materials
by the finite element method, Journal of
Reinforced Plastics and Composites 17(16),
1472-1493.
80.
Babu, C.S. and Kant, T. (1999), Two shear
deformable finite element models for buckling analysis of skew fibre-reinforced composite and sandwich panels, Composite Structures 46(2), 115-124.
81.
Shah, M.S. and Kant, T. (1999), Finite element analysis of fibre reinforced polymer shells using higher-order shear
deformation theories on parallel distributed memory machines, Int. J. Computer Applications in Technology 12(2/3/4/5), 206-210.
82.
Goswami,
S. and Kant, T. (1999), Large amplitude vibration of polymer composite
stiffened laminates by finite element method, Journal of Reinforced Plastics and Composites 18(5), 421-436.
83.
Babu, C.S. and Kant, T. (2000), Refined
higher-order finite element models for thermal buckling of composite laminates
and sandwich plates, J. Thermal Stresses 23(2), 111-130.
84.
Kant, T. and Swaminathan, K. (2000),
Estimation of transverse/ interlaminar stresses in
laminated composites-a selective review and survey of current developments, Composite Structures 49, 65-75.
85.
Kant, T. and Babu, C.S. (2000), Thermal buckling
analysis of skew fibre-reinforced composite and
sandwich plates using shear deformable finite element models, Composite Structures 49, 77-85.
86.
Ramana, V.P.V., Kant, T., Morton, S.E., Dutta, P.K.,
Mukherjee, A. and Desai, Y.M. (2000), Behavior of CFRPC strengthened reinforced
concrete beams with varying degrees of strengthening, Composites: Part B 31, 461-470.
87.
Kant, T. and Swaminathan, K. (2000),
Analytical solutions using a higher order refined theory for the stability
analysis of laminated composite and sandwich plates, Structural Engineering and Mechanics: An International Journal 10(4), 337-357.
88.
Chitnis, M.R., Desai, Y.M. and Kant, T. (2000), Edge
vibrations in composite laminated sandwich plates by using a higher order
displacement based theory, Journal of
Sound and Vibration 238(5),
791-807.
89.
Kant, T. and Swaminathan, K. (2001), Free
vibration of isotropic, orthotropic, and multilayer plates based on higher
order refined theories, Journal of Sound
and Vibration 241(2), 319-327.
90.
Kant, T. and Swaminathan, K (2001),
Analytical solutions for free vibration of laminated composite and sandwich
plates based on a higher-order refined theory, Composite Structures 53,
73-85.
91.
Kant, T. and Swaminathan, K. (2002),
Analytical solutions for the static analysis of laminated composite and
sandwich plates based on a higher order refined theory, Composite Structures 56,
329-344.
92.
Kant, T. and Gadgil, M.G. (2002), Analysis
of orthotropic plates based on three theories by segmentation method, Mechanics of Advanced Materials and
Structures 9(3), 189-239.
93.
Khare, R.K., Kant, T. and Garg, A.K. (2003),
Closed-form thermo-mechanical solutions of higher-order theories of cross-ply
laminated shallow shells, Composite
Structures 59(3), 313-340.
94.
Kulkarni, S.C., Desai, Y.M., Kant, T., Reddy, G.R., Parulekar, Y. and Vaze, K.K.
(2003), Uniaxial and biaxial ratchetting study of SA333 Gr.6 steel at room
temperature, International Journal of
Pressure Vessels and Piping 80,
179-185.
95.
Chitnis, M.R., Desai, Y.M., Shah, A.H. and Kant, T.
(2003), Comparisons of displacement-based theories for waves and vibrations in
laminated and sandwich composite plates, Journal
of Sound and Vibration 263,
617-642.
96.
Chitnis, M.R., Desai, Y.M. and Kant, T. (2003),
Scattering of waves in laminated composite plates, Advances in Vibration Engineering 2(3), 245-258.
97.
Khare, R.K., Kant, T. and Garg, A.K. (2004), Free
vibration of composite and sandwich laminates with a higher-order facet shell
element, Composite Structures 65 (3-4), 405-418.
98.
Kulkarni, S.C., Desai, Y.M., Kant, T., Reddy, G.R., Prasad, P., Vaze, K.K. and Gupta, C. (2004), Uniaxial and biaxial
ratcheting in piping materials – experiments and analysis, International Journal of Pressure Vessels and Piping 81(7),
609-617.
99.
Chitnis, M.R., Desai, Y.M., Shah, A.H. and Kant, T.
(2005), Elastodynamic Green’s function for reinforced
concrete beams, International Journal of
Solids and Structures 42(15), 4414-4435.
100.
Khare, R.K., Garg, A.K. and Kant, T. (2005), Free vibration of sandwich laminates with two higher-order
shear deformable facet shell element models, Journal of Sandwich Structures
and Materials 7(3),
221-244.
101.
Garg, A.K., Khare, R.K. and Kant, T. (2006),
Free vibration of skew fiber-reinforced composite and
sandwich laminates using a shear deformable finite element model, Journal of
Sandwich Structures and Materials 8(1), 33-53.
102.
Garg, A.K., Khare, R.K. and Kant, T. (2006),
Higher-order closed-form solutions for free vibration of laminated composite
and sandwich shells, Journal of Sandwich Structures and Materials 8(2), 95-124.
103.
Garg, A.K., Khare, R.K. and Kant, T. (2006),
Higher-order closed-form solutions for free vibration of laminated composite
and sandwich shells, Journal of Sandwich Structures and Materials 8(2), 205-235.
104.
Pendhari, S.S., Kant, T. and Desai, Y.M. (2006),
Non-linear analysis of reinforced concrete beams strengthened with polymer
composites, Structural Engineering and Mechanics- An International Journal
24(1), 1-18.
105.
Marur, S.R. and Kant, T. (2007), On
the angle ply higher order beam vibrations, Computational Mechanics 40,
25-33.
106.
Khante, S.N., Rode, V. and Kant, T. (2007),
Nonlinear transient dynamic response of damped plates using a higher order
shear deformation theory, Nonlinear Dynamics 47, 389-403.
107.
Kant, T., Pendhari, S.S. and Desai, Y.M.
(2007), A general partial discretization methodology for interlaminar
stress computation in composite laminates, Computer Modeling in Engineering
& Science 17(2), 135-161.
108.
Kant,
T., Pendhari, S.S. and Desai, Y.M. (2007), On accurate stress analysis of composite and sandwich narrow
beams, International Journal for Computational Methods in Engineering
Science and Mechanics 8(3), 165-177.
109.
Kant, T.,
Pendhari, S.S. and Desai, Y.M. (2007), A new
partial finite element model for statics of sandwich plates, Journal of Sandwich Structures and Materials
9(5), 487-520.
110.
Kant,
T., Pendhari S.S. and Desai Y.M. (2007), A novel finite element-numerical integration model for
composite laminates supported on opposite edges, ASME Journal of Applied Mechanics 74, 1114-1124.
111.
Kant,
T., Pendhari, S.S. and Desai, Y.M. (2007), Two dimensional stress analyses of laminates under thermal
load, Proceeding of the Indian National
Science Academy 73(3), 137-145.
112.
Kant,
T., Desai Y.M. and Pendhari, S.S. (2008), Stress analyses of
laminates under cylindrical bending,
Communications in Numerical Methods in Engineering 24, 15-32.
113.
Kant T.,
Gupta, A.B., Pendhari, S.S. and Desai, Y.M. (2008), Elasticity
solution of cross-ply composite and sandwich plates, Composite Structures 83, 13-24.
114.
Kant, T., Pendhari, S.S.
and Desai, Y.M. (2008), An efficient semi-analytical model for composite and
sandwich plates subjected to thermal load, Journal
of Thermal Stresses 31, 77-103.
115.
Marur, S.R.
and Kant, T. (2008), Free vibration of higher-order sandwich and composite
arches, Part I: Formulation, Journal of Sound and Vibration 310, 91-109.
116.
Marur, S.R.
and Kant, T. (2008), Free vibration of higher-order sandwich and composite
arches, Part II: Frequency spectra analysis, Journal
of Sound and Vibration 310, 110-133.
117.
Pendhari, S.S., Kant, T. and Desai, Y.M. (2008), Application of composite
materials in civil engineering: A general review, Composite Structures 84(2), 114-124.
118.
Kant, T.
and Shiyekar, S.M. (2008), Cylindrical bending of
piezoelectric laminates with a higher order shear and normal deformation
theory, Computers and Structures 86, 1594-1603.
119.
Kant,
T., Pendhari, S.S. and Desai, Y.M. (2008), A new partial discretization methodology for narrow
composite beams under plane stress condition, International Journal of
Computational Methods 5(3), 381-401.
120.
Garg,
A.K., Khare, R.K. and Kant, T. (2008), Free vibration of laminated composite and sandwich folded
plates using a higher-order shear deformable finite element model, CSVTU Research Journal 1(2), 22-33.
121.
Marur, S.R.
and Kant, T. (2009), On the flexural analysis of sandwich and
composite arches through an isoparametric
higher-order model, ASCE Journal of Engineering Mechanics 135(7), 614-631.
122.
Shiyekar, S.M. and Kant, T. (2010), An
electromechanical higher order model for piezoelectric functionally graded
plates, International Journal of
Mechanics and Materials in Design 6(2),
163-174.
123.
Pendhari, S.S., Kant, T., Desai, Y.M. and Subbaiah, C.V. (2010), On deformation of functionally
graded narrow beams under transverse loads,
International Journal of Mechanics and Materials in Design 6(3), 269-282.
124.
Kant, T. and Desai, P. (2010), Two-dimensional
axisymmetric electromechanical response of piezoelectric, functionally graded
and layered composite cylinders, Journal of Solid Mechanics 2(4), 403-417.
125.
Marur, S.R. and Kant, T. (2011), Transient dynamic
analysis of higher order sandwich and composite arches, Composite Structures 93(4),
1201-1216.
126.
Desai,
P. and Kant, T. (2011), On accurate stress determination in laminated finite
length cylinders subjected to thermo elastic load, International Journal of Mechanics and
Solids (IJM&S) 6(1), 7-26.
127.
Kant, T.
and Deasi, P. (2011), On
numerical analysis of finite length cylinders under pressure: An elastostatic computational approach, International Journal of Applied Computational Science and Mathematics
1(1), 1-22.
128.
Shiyekar, S.M.
and Kant, T. (2011), Higher order shear deformation
effects on analysis of laminates with piezoelectric fibre
reinforced composite actuators, Composite
Structures 93, 3252-3261.
129.
Desai,
P. and Kant, T. (2011), Stress analysis of finite length cylinders of layered
media, Applied and Computational
Mechanics 5(2), 129-142.
130.
Desai, P. and Kant, T. (2012), A mixed semi analytical solution for
functionally graded (FG) finite length cylinders of orthotropic materials
subjected to thermal load, International Journal of Mechanics and
Materials in Design 8(1),
89-100.
131.
Pendhari, S.S.,
Kant, T., Desai, Y.M. and Venkata Subbaiah,
C. (2012), Static solutions for functionally graded simply supported plates, International Journal of Mechanics and
Materials in Design 8(1), 51-69.
132.
Desai,
P. and Kant, T. (2012), Accurate stresses in laminated piezoelectric finite
length cylinders subjected to electro-thermo-mechanical loadings, Current Science 102(1), 50-60.
133.
Jha, D.K., Kant, T. and
Singh, R.K. (2012), Higher order shear and normal deformation theory for
natural frequency of functionally graded rectangular plates, Nuclear
Engineering and Design 250, 8-13.
134.
Desai,
P. and Kant, T. (2012), Accurate numerical
modeling for functionally graded (FG) cylinders of finite length subjected
to thermo mechanical load, Journal of Structural Engineering 39(3), 277-290.
135.
Kant, T.
and Shiyekar, S.M. (2013), An assessment of a higher
order theory for composite laminates subjected to thermal gradient, Composite Structures 96, 698-707.
136.
Jha, D.K., Kant, T. and
Singh, R.K. (2013), Free vibration response of functionally graded thick plates
with shear and normal deformations effects, Composite Structures 96,
799-823.
137.
Jha, D.K., Kant, T. and
Singh, R.K. (2013), A critical review of recent research on functionally graded
plates, Composite Structures 96, 833-849.
138.
Jha, D.K., Kant, T. and
Singh, R.K., (2013), Free vibration of functionally graded plates with a higher
order shear and normal deformation theory,
International Journal of Structural Stability and Dynamics 13(1), 1350004:1-26 .
139.
Desai,
P. and Kant, T. (2013), On numerical analysis of
composite and laminated cylinders of finite length subjected to partially
distributed load, International Journal
of Pressure Vessels and Piping 111-112,
321-330.
140.
Kant,
T., Tripathi, R.K. and Rode, V. (2013),
Elastic-plastic behavior of thick plates with a higher-order shear deformation
theory, Proceedings of the Indian
National Science Academy 79(4),
563-574.
141.
Jha, D.K. Kant, T. and
Singh, R.K. (2013), Stress analysis of transversely loaded functionally graded
plates with a higher order shear and normal deformation theory, ASCE Journal of Engineering Mechanics 139(12), 1663-1680.
142.
Jha, D.K., Kant, T., Srinivas, K. and Singh, R.K.
(2013), An accurate higher order displacement model with shear and normal
deformations effects for functionally graded plates, Fusion Eng. Des. 96, 799-823.
143.
Kant,
T., Jha, D.K. and Singh, R.K. (2014), A higher-order
shear and normal deformation functionally graded plate model: some recent
results, Acta Mechanica 225(7),
2865-2876.
144.
Jha, D.K., Kant, T., Srinivas, K. and Singh, R.K.
(2014), An accurate two-dimensional theory for
deformation and stress analyses of functionally graded thick plates, International Journal of Advanced Structural Engineering (IJASE) 6(2), 1-11.
145.
Jha, D.K., Srinivas,
K., Kant, T. and Singh, R.K. (2014), Assessment of Higher Order Shear and
Normal Deformations Theories for Stress Analysis and Free Vibration of
Functionally Graded Plates, BARC Newsletter, Issue No. 340, 13-21.
146.
Reddy,
K.S.K. and Kant, T. (2014), Three
dimensional elasticity solution for free vibrations of exponentially graded
plates, ASCE Journal of Engineering Mechanics,
140(7).
147.
Desai,
P. and Kant, T. (2015), On numerical analysis of
axisymmetric thick cylindrical shells based on higher order shell theories by
segmentation method, Journal of Sandwich
Structures and Materials 17(2)
(2015) 130-169.
148.
Kosteski, L.E., Riera, J.D., Iturrioz, I., Singh,
R.K. and Kant, T. (2015), Analysis of reinforced concrete
plates subjected to impact employing the truss-like discrete element method,
Fatigue & Fracture of Engineering
Materials & Structures (FFEMS) 38(3) (2015): 276-289.
149.
Kosteski, L.E., Riera, J.D., Iturrioz, I., Singh,
R.K. and Kant, T. (2015), DEM based assessment of empirical formulas for
prediction of the effects of projectile impact on concrete structures,
Fatigue & Fracture of Engineering
Materials & Structures (FFEMS) 38(8)
(2015): 948-959.
150.
Pendhari, S.S.,
Mahajan, M. and Kant, T. (2017), Static analysis of functionally graded
laminates according to power law variation of elastic modulus under
bidirectional bending, International
Journal of Computational Methods 14(5),
- .
151.
Kant, T.
and Punera, D. (2017), A refined higher order theory
for statics and dynamics of doubly curved shells, Proceedings of the Indian
National Science Academy 83(3),
611-630.
152.
Punera, D. and
Kant, T. (2017), Free vibration of functionally graded open cylindrical shells
based on several refined higher order displacement models, Thin Walled Structures 119C,
707-726.
153.
Punera, D. and
Kant, T. (2017), Elasto-statics of laminated and
functionally graded sandwich cylindrical shells with two refined higher order
models, Composite Structures 182, 505-523.
154.
Punera, D.,
Kant, T. and Desai, Y.M. (2018), Thermo-elastic analysis of laminated and
functionally graded sandwich cylindrical shells with two refined higher order
models, Journal of Thermal Stresses 41(1), 54-79.
155.
LomtePatil,
Y.T., Kant, T., Desai, Y.M., (2018), Comparision of
three dimensional elasticity solutions for functionally graded plates,
Composite Structures 2018. Avilable online
156.
Punera, D.,
Kant, T., and Desai, Y.M., A critical review of recent studies on functionally
graded shells, Composite Structures (revision submitted to the journal;
acceptance awaited)