How to search?
advanced search

Search results

Filters

  • Journals
  • Authors
  • Keywords
  • Date
  • Type

Search results

Number of results: 4
items per page: 25 50 75
Sort by:

A two dimensional problem on laser pulse heating in thermoelastic microelongated solid

Praveen Ailawalia Sunil Kumar Sachdeva Devinder Singh Pathania
Archives of Thermodynamics | 2019 | vol. 40 | No 2 | 69-85 | DOI: 10.24425/ather.2019.129542
Keywords Laser pulse thermoelasticity Normal mode Microelongation
Download PDF Download RIS Download Bibtex

Abstract

The Bulletin of the Polish Academy of Sciences: Technical Sciences (Bull.Pol. Ac.: Tech.) is published bimonthly by the Division IV Engineering Sciences of the Polish Academy of Sciences, since the beginning of the existence of the PAS in 1952. The journal is peer‐reviewed and is published both in printed and electronic form. It is established for the publication of original high quality papers from multidisciplinary Engineering sciences with the following topics preferred: Artificial and Computational Intelligence, Biomedical Engineering and Biotechnology, Civil Engineering, Control, Informatics and Robotics, Electronics, Telecommunication and Optoelectronics, Mechanical and Aeronautical Engineering, Thermodynamics, Material Science and Nanotechnology, Power Systems and Power Electronics.

Journal Metrics: JCR Impact Factor 2018: 1.361, 5 Year Impact Factor: 1.323, SCImago Journal Rank (SJR) 2017: 0.319, Source Normalized Impact per Paper (SNIP) 2017: 1.005, CiteScore 2017: 1.27, The Polish Ministry of Science and Higher Education 2017: 25 points.

Abbreviations/Acronym: Journal citation: Bull. Pol. Ac.: Tech., ISO: Bull. Pol. Acad. Sci.-Tech. Sci., JCR Abbrev: B POL ACAD SCI-TECH Acronym in the Editorial System: BPASTS.

Go to article

Authors and Affiliations

Praveen Ailawalia
Sunil Kumar Sachdeva
Devinder Singh Pathania

Effect of rotation on a semiconducting medium with two-temperatures under L-S theory

Mohamed I.A. Othman Ramadan S. Tantawi Ebtesam E.M. Eraki
Archives of Thermodynamics | 2017 | No 2 | 101-122 | DOI: 10.1515/aoter-2017-0012
Keywords normal mode analysis Lord-Shulman theory rotation conductive temperature semiconductors
Download PDF Download RIS Download Bibtex

Abstract

The model of the equations of generalized thermoelasticity in a semi-conducting medium with two-temperature is established. The entire elastic medium is rotated with a uniform angular velocity. The formulation is applied under Lord-Schulman theory with one relaxation time. The normal mode analysis is used to obtain the expressions for the considered variables. Also some particular cases are discussed in the context of the problem. Numerical results for the considered variables are obtained and illustrated graphically. Comparisons are also made with the results predicted in the absence and presence of rotation as well as two-temperature parameter.

Go to article

Authors and Affiliations

Mohamed I.A. Othman
Ramadan S. Tantawi
Ebtesam E.M. Eraki

Dedispersion Transform Method for Extracting the Normal Modes of a Shallow Water Acoustic Signal in the Pekeris Waveguide

Guang-Bing Yang Lian-Gang Lü Da-Zhi Gao Ying Jiang Hong-Ning Liu
Archives of Acoustics | 2015 | vol. 40 | No 1 | 11-18 | DOI: 10.1515/aoa-2015-0002
Keywords normal mode extraction dedispersion transform Pekeris waveguide source ranging
Download PDF Download RIS Download Bibtex

Abstract

The normal modes cannot be extracted even in the Pekeris waveguide when the source-receiver distance is very close. This paper introduces a normal mode extraction method based on a dedispersion transform (DDT) to solve this problem. The method presented here takes advantage of DDT, which is based on the waveguide invariant such that the dispersion associated with all of the normal modes is removed at the same time. After performing DDT on a signal received in the Pekeris waveguide, the waveform of resulting normal modes is very close to the source signal, each with different position and amplitude. Each normal mode can be extracted by determining its position and amplitude parameters by applying particle swarm optimization (PSO). The waveform of the extracted normal mode is simply the waveform of the source signal; the real waveform of the received normal mode can then be recovered by applying dispersion compensation to the source signal. The method presented needs only one receiver and is verified with experimental data
Go to article

Authors and Affiliations

Guang-Bing Yang
Lian-Gang Lü
Da-Zhi Gao
Ying Jiang
Hong-Ning Liu

Refined multi-phase-lags theory and Thomson effect on a micropolar thermoelastic medium with voids

Amnah M. Alharbi Elsayed M. Abd-Elaziz Mohamed I.A. Othman
Archives of Thermodynamics | 2021 | vol. 42 | No 3 | 279-309 | DOI: 10.24425/ather.2021.138120
Keywords Micropolar Voids Refined-phase-lags theory Thomson effect Normal mode analysis
Download PDF Download RIS Download Bibtex

Abstract

The problem considered is that of an isotropic, micropolar thermoelastic medium with voids subjected to the Thomson effect. The solution to the problem is presented in the context of the refined multiphase- lags theory of thermoelasticity. The normal mode analysis was used to obtain the analytical expressions of the considered variables. The nondimensional displacement, temperature, microrotation, the change in the volume fraction field and stress of the material are obtained and illustrated graphically. The variations of these quantities have been depicted graphically in the refined-phase-lag theory, Green and Naghdi theory of type II, Lord and Shulman theory and a coupled theory. The effects of the Thomson parameter and phase lag parameters on a homogeneous, isotropic, micropolar thermoelastic material with voids are revealed and discussed. Some particular cases of interest are deduced from the present investigation.
Go to article

Bibliography

[1] Biot M.A.: Thermoelasticity and irreversible thermodynamics. J. Appl. Phys. 7(1956), 3, 240–253.
[2] Lord H.W., Shulman Y.: A generalized dynamical theory of thermoelasticity. J. Mech. Phys. Sol. 15(1967), 5, 299–309.
[3] Green A.E., Lindsay K.A.: Thermoelasticity. J. Elast. 2(1972), 1, 1–7.
[4] Green A.E., Naghdi P.M.: A re-examination of the basic postulates of thermosmechanics. Proc. R. Soc. Lond. A 432(1991), 1885, 171–194.
[5] Green A.E., Naghdi P.M.: On undamped heat wave in elastic solids. J. Therm. Stress. 15(1992), 2, 253–264.
[6] Green A.E., Naghdi P.M.: Thermoelasticity without energy dissipation. J. Elast. 31(1993), 189–209.
[7] Tzou D.Y.: The generalized lagging response in small-scale and high-rate heating. Int. J. Heat Mass Trans. 38(1995), 17, 3231–3240.
[8] Tzou D.Y.: A unified field approach for heat conduction from macro- to microscales. J. Heat Trans. 117(1995), 1, 8–16.
[9] Roy Choudhuri S.K.: On a thermoelastic three-phase-lag model. J. Therm. Stress. 30(2007), 3, 231–238.
[10] Eringen A.C.: Linear theory of micropolar elasticity. ONR Techn. Rep. 29 (School of Aeronautics, Aeronautics and Engineering Science), Purdue Univ., West Lafayett 1965.
[11] Eringen A.C.: A unified theory of thermomechanical materials. Int. J. Eng. Sci. 4(1966), 2, 179–202.
[12] Eringen A.C.: Linear theory of micropolar elasticity. J. Math. Mech. 15(1966), 6, 909–924.
[13] Nowacki W.: Couple stresses in the theory of thermoelasticity III. Bull. Acad. Pol. Sci. Tech. Ser. Sci. Tech. 14(1966), 8, 801–809.
[14] Tauchert T.R., Claus Jr. W.D., Ariman T.: The linear theory of micropolar thermo- elasticity. Int. J. Eng. Sci. 6(1968), 1, 36–47.
[15] Nowacki W., Olszak W. (Eds.): Micropolar Thermoelasticity. CISM Courses and Lectures 151, Springer-Verlag, Vienna 1974.
[16] Dhaliwal R.S., Singh A.: Micropolar thermoelasticity. In: Thermal Stresses II (R.B. Hetnarski, Ed.), Elsevier, Amsterdam 1987.
[17] Marin M., Nicaise S.: Existence and stability results for thermoelastic dipolar bodies with double porosity. Continuum Mech. Thermodyn. 28(2016), 6, 1645–1657.
[18] Marin M., Ellahi R., Chirila A.: On solutions of Saint–Venant’S problem for elastic dipolar bodies with voids. Carpathian J. Math. 33(2017), 2, 219–232.
[19] Othman M.I.A., Hasona W.M., Abed-Elaziz E.M.: Effect of rotation on micropolar generalized thermoelasticity with two temperatures using a dual-phase lag model. Can. J. Phys. 92(2014), 2, 148–159.
[20] Othman M.I.A., Hasona W.M., Abed-Elaziz E.M.: The influence of thermal loading due to laser pulse on generalized micropolar thermoelastic solid with comparison of different theories. Multi. Model. Mater. Struct. 10(2014), 3, 328–345.
[21] Chandrasekharaiah D.S.: Heat flux dependent micropolar thermoelasticity. Int. J. Eng. Sci. 24(1986), 8, 1389–1395.
[22] Othman M.I.A., Hasona W.M., Abed-Elaziz E.M.: Effect of rotation and initial stresses on generalized micropolar thermoelastic medium with three-phase-lag. J. Comput. Theor. Nanosci. 12(2015), 9, 2030–2040.
[23] Othman M.I.A., Abed-Elaziz E.M.: Effect of rotation and gravitational on a micropolar magneto-thermoelastic medium with dual-phase-lag model. Microsyst. Tech. 23(2017), 10, 4979–4987.
[24] Othman M.I.A., Abd-alla A.N., Abed-Elaziz E.M.: Effect of heat laser pulse on wave propagation of generalized thermoelastic micropolar medium with energy dissipation. Ind. J. Phys. 94(2020), 3, 309–317.
[25] Cowin S.C., Nunziato J.W.: Linear elastic materials with voids. J. Elast. 13(1983), 2, 125–147.
[26] Othman M.I.A., Abed–Elaziz E.M.: The effect of thermal loading due to laser pulse in generalized thermoelastic medium with voids in dual-phase-lag model. J. Therm. Stress. 38(2015), 9, 1068–1082.
[27] Abd-Elaziz E.M., Othman M.I.A.: Effect of Thomson and thermal loading due to laser pulse in a magneto-thermoelastic porous medium with energy dissipation. ZAMM-Z. Angew. Math. Me. 99(2019), 8, 201900079.
[28] Abd-Elaziz E.M., Marin M., Othman M.I.A.: On the effect of Thomson and initial stress in a thermos-porous elastic solid under G-N electromagnetic theory. Symmetry. 11(2019), 3, 413–430.
[29] Othman M.I.A., Marin M.: Effect of thermal loading due to laser pulse on thermoelastic porous media under G-N theory. Results Phys. 7(2017), 3863–3872.
[30] Othman M.I.A, Abd-Elaziz E.M.: Plane waves in a magneto-thermoelastic solids with voids and microtemperatures due to hall current and rotation. Results Phys. 7(2017), 4253–4263.
[31] Othman M.I.A., Tantawi R.S., Eraki E.E.M.: Effect of rotation on a semi conducting medium with two-temperature under L–S theory. Arch. Thermodyn. 38(2017), 2, 101–122.
[32] Chirita S., Ciarletta M., Tibullo V.: On the thermomechanical consistency of the time differential dual-phase-lag models of heat conduction. Int. J. Heat Mass Tran. 114(2017), 277–285.
[33] https://matlab.mathworks.com/ (accessed 17 Feb. 2021)
Go to article

Authors and Affiliations

Amnah M. Alharbi
1
Elsayed M. Abd-Elaziz
2
Mohamed I.A. Othman
3
  1. Taif University, Department of Mathematics, College of Science, P.O. Box 11099, Taif, 21944, Saudi Arabia
  2. Ministry of Higher Education, Zagazig Higher Institute of Engineering & Technology, Zagazig, Egypt
  3. Zagazig University, Department of Mathematics, Faculty of Science, P.O. Box 44519, Zagazig, Egypt

This page uses 'cookies'. Learn more