How to cite this paper
Othman, M., Eraki, E., Atwa, S & Ismail, M. (2023). Thermoelastic micro-stretch solid immersed in an infinite inviscid fluid and subject to a rotation under two theories.Engineering Solid Mechanics, 11(3), 299-310.
Refrences
Abouelregal, A.E., Marin, M., & Askar, S. (2021). Thermo-optical mechanical waves in a rotating solid semiconductor sphere using the improved Green–Naghdi III model. Mathematics, 9(22), 2902.
Abouelregal, A. E., Sedighi, H. M., & Shirazi, A. H. (2022). The effect of excess carrier on a semiconducting semi-infinite medium subject to a normal force by means of Green and Naghdi approach. Silicon, 14(9), 4955-4967.
Deswal, S., Sheoran, D., Thakran, S., & Kalkal, K. K. (2022). Reflection of plane waves in a nonlocal microstretch thermoelastic medium with temperature dependent properties under three-phase-lag model. Mechanics of Advanced Materials and Structures, 29(12), 1692-1707.
Kumar, R., & Partap, G. (2009). Wave propagation in microstretch thermoelastic plate bordered with layers of inviscid liquid. Multidiscipline Modeling in Materials and Structures, 5, 171-184.
Kumar, S., Sharma, J. N., & Sharma, Y. D. (2011). Generalized thermoelastic waves in micro-stretch plates loaded with fluid of varying temperature. International Journal of Applied Mechanics, 3(3), 563-586.
Kumar, R., & Chawla, V. (2011). A study of plane wave propagation in anisotropic three-phase-lag and two-phase-lag model. International Communications in Heat and Mass Transfer, 38(9), 1262-1268.
Kumar, R., Ahuja, S., & Garg, S. K. (2014). Surface wave propagation in a micro-stretch thermoelastic diffusion material under an inviscid liquid layer. Advances in Acoustics and Vibration, 2014.
Kumar, R. (2015). Wave propagation in a microstretch thermoelastic diffusion solid. Analele ştiinţifice ale Universităţii "Ovidius" Constanţa. Seria Matematică, 23(1), 127-170.
Kutbi, M. A., & Zenkour, A. M. (2021) Thermomechanical waves in an axi-symmetric rotating disk using refined Green–Naghdi models. International Journal of Applied Mechanics, 13(03), 2150035.
Lata, P., & Himanshi, H. (2022). Fractional effect in an orthotropic magneto-thermo-elastic rotating solid of type GN-II due to normal force. Structural Engineering and Mechanics, 81(4), 503-511.
Marin, M., & Öchsner, A. (2018) An initial boundary value problem for modeling a piezoelectric dipolar body. Continuum Mechanics and Thermodynamics, 30, 267–278.
Marin, M., Öchsner, A. & Taus, D. (2020) On structural stability for an elastic body with voids having dipolar structure. Continuum Mechanics and Thermodynamics, 32, 147–160.
Marin, M., Ochsner, A., & Othman, M. I. A. (2022). On the evolution of solutions of mixed problem in thermoelasticity of porous bodies with dipolar structure. Continuum Mechanics and Thermodynamics, 34(2), 491-506
Miszuris, W., & Öchsner, A. (2013). Universal transmission conditions for thin reactive heat-conducting interphases. Continuum Mechanics and Thermodynamics, 25, 1–21.
Othman, M. I. A., & Atwa, S. Y. (2014). Effect of rotation on a fiber-reinforced thermo-elastic under Green-Naghdi theory and influence of gravity. Meccanica, 49(1), 23-36.
Othman, M. I. A., Said, S. M., & Marin, M. (2019). A novel model of plane waves of two-temperature fiber-reinforced thermoelastic medium under the effect of gravity with three-phase-lag model. International Journal of Numerical Methods for Heat and Fluid Flow, 29(12), 4788-4806.
Othman, M. I. A., Atwa, S. Y., Eraki, E. E., & Ismail, M. F. (2021). The initial stress effect on a thermoelastic micro-elongated solid under the dual-phase-lag model. Applied Physics A., 127(9), 1-8.
Othman, M. I. A., & Abbas, I. A. (2021). 2-D problem of micropolar thermoelastic rotating medium with eigenvalue approach under the three-phase-lag model. Waves Random Complex Media. DOI: 10.1080/17455030.2021.1879405
Othman, M. I. A., Atwa, S. Y., Eraki, E. E., & Ismail, M. F. (2021). A thermoelastic micro-elongated layer under the effect of gravity in the context of the dual-phase lag model. Journal of Applied Mathematics and Mechanics, 101(12), e202100109
Othman, M. I. A., Ismail, M. F. (2022). The gravitational field effect on a micro-elongated thermoelastic layer under the fluid load, using the lord-shulman theory and dual-phase-lag model. Multidiscipline Modeling in Materials and Structures, 18(5), 757-771.
Roy Choudhuri, S. K. (2007). On a thermoelastic three-phase-lag model. Journal of Thermal Stresses, 30(3), 231-238.
Sharma, J. N., Kumar, S., & Sharma, Y. D. (2007) Propagation of Rayleigh surface waves in microstretch thermoelastic continua under inviscid fluid loadings. Journal of Thermal Stresses, 31(1), 18-39
Sharma, D. K., Sharma, M. K., & Sarkar, N. (2021). Effect of three-phase-lag model on the analysis of three-dimensional free vibrations of viscothermoelastic solid cylinder. Applied Mathematical Modelling, 90, 281-301.
Singh, B., & Singla, H. (2020). The effect of rotation on the propagation of waves in an incompressible transversely isotropic thermoelastic solid. Acta Mechanica, 231(1), 2485-2495.
Sur, A., & Kanoria, M. (2014) Thermoelastic interaction in a viscoelastic functionally graded half-space under three-phase-lag model. European Journal of Computational Mechanics, 23(5-6), 179-198.
Sur, A. (2022). Memory responses in a three-dimensional thermo-viscoelastic medium. Waves Random Complex Media, 32(1), 137-154.
Xu, C. G., Xu, B. Q., & Xu, G. D. (2011). Laser-induced thermoelastic Leaky Lamb waves at the fluid–solid interface. Applied Physics A., 105(2), 379-386.
Youssef, H. M., & El-Bary, A. A. (2022) Characterization of the photothermal interaction of a semiconducting solid sphere due to the mechanical damage and rotation under Green-Naghdi theories. Mechanics of Advanced Materials and Structures, 29(6), 889-904.
Abouelregal, A. E., Sedighi, H. M., & Shirazi, A. H. (2022). The effect of excess carrier on a semiconducting semi-infinite medium subject to a normal force by means of Green and Naghdi approach. Silicon, 14(9), 4955-4967.
Deswal, S., Sheoran, D., Thakran, S., & Kalkal, K. K. (2022). Reflection of plane waves in a nonlocal microstretch thermoelastic medium with temperature dependent properties under three-phase-lag model. Mechanics of Advanced Materials and Structures, 29(12), 1692-1707.
Kumar, R., & Partap, G. (2009). Wave propagation in microstretch thermoelastic plate bordered with layers of inviscid liquid. Multidiscipline Modeling in Materials and Structures, 5, 171-184.
Kumar, S., Sharma, J. N., & Sharma, Y. D. (2011). Generalized thermoelastic waves in micro-stretch plates loaded with fluid of varying temperature. International Journal of Applied Mechanics, 3(3), 563-586.
Kumar, R., & Chawla, V. (2011). A study of plane wave propagation in anisotropic three-phase-lag and two-phase-lag model. International Communications in Heat and Mass Transfer, 38(9), 1262-1268.
Kumar, R., Ahuja, S., & Garg, S. K. (2014). Surface wave propagation in a micro-stretch thermoelastic diffusion material under an inviscid liquid layer. Advances in Acoustics and Vibration, 2014.
Kumar, R. (2015). Wave propagation in a microstretch thermoelastic diffusion solid. Analele ştiinţifice ale Universităţii "Ovidius" Constanţa. Seria Matematică, 23(1), 127-170.
Kutbi, M. A., & Zenkour, A. M. (2021) Thermomechanical waves in an axi-symmetric rotating disk using refined Green–Naghdi models. International Journal of Applied Mechanics, 13(03), 2150035.
Lata, P., & Himanshi, H. (2022). Fractional effect in an orthotropic magneto-thermo-elastic rotating solid of type GN-II due to normal force. Structural Engineering and Mechanics, 81(4), 503-511.
Marin, M., & Öchsner, A. (2018) An initial boundary value problem for modeling a piezoelectric dipolar body. Continuum Mechanics and Thermodynamics, 30, 267–278.
Marin, M., Öchsner, A. & Taus, D. (2020) On structural stability for an elastic body with voids having dipolar structure. Continuum Mechanics and Thermodynamics, 32, 147–160.
Marin, M., Ochsner, A., & Othman, M. I. A. (2022). On the evolution of solutions of mixed problem in thermoelasticity of porous bodies with dipolar structure. Continuum Mechanics and Thermodynamics, 34(2), 491-506
Miszuris, W., & Öchsner, A. (2013). Universal transmission conditions for thin reactive heat-conducting interphases. Continuum Mechanics and Thermodynamics, 25, 1–21.
Othman, M. I. A., & Atwa, S. Y. (2014). Effect of rotation on a fiber-reinforced thermo-elastic under Green-Naghdi theory and influence of gravity. Meccanica, 49(1), 23-36.
Othman, M. I. A., Said, S. M., & Marin, M. (2019). A novel model of plane waves of two-temperature fiber-reinforced thermoelastic medium under the effect of gravity with three-phase-lag model. International Journal of Numerical Methods for Heat and Fluid Flow, 29(12), 4788-4806.
Othman, M. I. A., Atwa, S. Y., Eraki, E. E., & Ismail, M. F. (2021). The initial stress effect on a thermoelastic micro-elongated solid under the dual-phase-lag model. Applied Physics A., 127(9), 1-8.
Othman, M. I. A., & Abbas, I. A. (2021). 2-D problem of micropolar thermoelastic rotating medium with eigenvalue approach under the three-phase-lag model. Waves Random Complex Media. DOI: 10.1080/17455030.2021.1879405
Othman, M. I. A., Atwa, S. Y., Eraki, E. E., & Ismail, M. F. (2021). A thermoelastic micro-elongated layer under the effect of gravity in the context of the dual-phase lag model. Journal of Applied Mathematics and Mechanics, 101(12), e202100109
Othman, M. I. A., Ismail, M. F. (2022). The gravitational field effect on a micro-elongated thermoelastic layer under the fluid load, using the lord-shulman theory and dual-phase-lag model. Multidiscipline Modeling in Materials and Structures, 18(5), 757-771.
Roy Choudhuri, S. K. (2007). On a thermoelastic three-phase-lag model. Journal of Thermal Stresses, 30(3), 231-238.
Sharma, J. N., Kumar, S., & Sharma, Y. D. (2007) Propagation of Rayleigh surface waves in microstretch thermoelastic continua under inviscid fluid loadings. Journal of Thermal Stresses, 31(1), 18-39
Sharma, D. K., Sharma, M. K., & Sarkar, N. (2021). Effect of three-phase-lag model on the analysis of three-dimensional free vibrations of viscothermoelastic solid cylinder. Applied Mathematical Modelling, 90, 281-301.
Singh, B., & Singla, H. (2020). The effect of rotation on the propagation of waves in an incompressible transversely isotropic thermoelastic solid. Acta Mechanica, 231(1), 2485-2495.
Sur, A., & Kanoria, M. (2014) Thermoelastic interaction in a viscoelastic functionally graded half-space under three-phase-lag model. European Journal of Computational Mechanics, 23(5-6), 179-198.
Sur, A. (2022). Memory responses in a three-dimensional thermo-viscoelastic medium. Waves Random Complex Media, 32(1), 137-154.
Xu, C. G., Xu, B. Q., & Xu, G. D. (2011). Laser-induced thermoelastic Leaky Lamb waves at the fluid–solid interface. Applied Physics A., 105(2), 379-386.
Youssef, H. M., & El-Bary, A. A. (2022) Characterization of the photothermal interaction of a semiconducting solid sphere due to the mechanical damage and rotation under Green-Naghdi theories. Mechanics of Advanced Materials and Structures, 29(6), 889-904.