Thermodynamic effects of linear dissipative small deformations

Journal of Thermal Analysis and Calorimetry

Volumn 100, Issue 3, 2010, Pages 941-947

  Anssari Benam, Afshin ^a   Viola, Giuseppe ^a   Korakianitis, Theodosios ^a  

^a QUEEN MARY UNIVERSITY OF LONDON   (United Kingdom)

Author keywords

Deformation heating effect; Force elongation; Internal energy; Linear deformation; Stretching calorimetry

Indexed keywords

FORCE-ELONGATION; HEATING EFFECT; INTERNAL ENERGIES; INTERNAL ENERGY; STRETCHING CALORIMETRY;

CALORIMETERS; ELONGATION; HEAT EXCHANGERS; HEATING; THERMODYNAMICS;

CALORIMETRY;

EID: 77954887409     PISSN: 13886150     EISSN: None     Source Type: Journal    
DOI: 10.1007/s10973-009-0349-0     Document Type: Conference Paper

References (23)

1. Müller FH. Thermodynamics of deformation, calorimetric investigation of deformation processes. Rheology. 1998;5:417-89.
2. Ferguson HF, Frurip DJ, Pastor AJ, Peerey LM, Whiting LF. A review of analytical applications of calorimetry. Thermochim Acta. 2000;363:1-21.
3. Lyon RE, Farris RJ. Thermodynamic behavior of solid polymers in uniaxial deformation. Polym Eng Sci. 1984;24:908-14.
4. Nowacki W. In: Francis PH, Hetnarski RB, editors. Dynamic problems of thermoelasticity. Leyden, The Netherlands: Noordhoff International Publishing; 1975.
5. Zener C. Internal frictions in solids. Phys Rev. 1937;53:90-9.
6. Biot M. Thermoelasticity and irreversible thermodynamics. J Appl Phys. 1956;27:240-53.
7. Dassios G, Grillakis M. Dissipation rates and partition of energy in thermoelasticity. Arch Rat Mech Anal. 1984;87:49-91.
8. Khisaeva ZF, Ostoja-Starzewski M. Thermoelastic damping in nanomechanical resonators with finite wave speeds. J Therm Stress. 2006;29:201-16.
9. Prabhakar S, Vengallatore S. Theory of thermoelastic damping in micromechanical resonators with two-dimensional heat conduction. J Microelectromech Syst. 2008;17:494-502.
10. Lakes R. Thermoelastic damping in materials with a complex coefficient of thermal expansion. J Mech Behav Mater. 1997;8:201-9.
11. Pitarresi G. A review of the general theory of thermoelastic stress analysis. J Stress Anal. 2003;38:405-17.
12. Price C. Thermodynamics of rubber elasticity. Proc R Soc Lond A. 1976;351:331-50.
13. Balta Calleja FJ, Privalko EG, Sukhorukov DI, Fainleib AM, Sergeeva LM, Shantalii TA, et al. Structure-property relationships for cyanurate-containing, full interpenetrating polymer networks. Polymer. 2000;41:4699-707.
14. Azura AR, Muhr AH, Göritz D, Thomas AG. Effect of ageing on the ability of natural rubber to strain crystallise. In: Busfield JJC, Muhr AH, editors. Constitutive models for rubber III. Lisse: Swets & Zeitlinger; 2003. p. 79-84.
15. Gyftopoulos EP, Beretta GP. Thermodynamics: foundations and applications. 2nd ed. New York: Dover Publications; 2005.
16. Göritz D. Thermodynamics of linear reversible deformation. J Polym Sci B. 1986;24:1839-48.
17. Privalko VP, Sukhorukov DI, Karger-Kocsis J. Thermoelastic behavior of carbon fiber/polycarbonate model composites. Polym Eng Sci. 1999;39:1525-33.
18. Karaman VM, Privalko EG, Privalko VP, Kubies D, Puffr R, Jerome R. Stretching calorimetry studies of poly (ε-caprolactone)/organoclay nanocomposites. Polymer. 2005;46:1943-8.
19. Reichert WF, Hopfenmuller MK, Göritz D. Volume change and gas transport at uniaxial deformation of filled natural rubber. J Mater Sci. 1987;22:3470-6.
20. Göritz D, Hafner OT. Thermodynamic analysis of polymer networks. In: Busfield JJC, Muhr AH, editors. Constitutive models for rubber II. Lisse: Swets & Zeitlinger; 2003. p. 291-7.
21. Dieng L, Haboussi M, Loukil M, Cunat C. A theory of inelasticity based on a non-equilibrium thermodynamic: application to yield surface prediction. Mech Mater. 2005;37:1069-81.
22. Gee G. The interaction between rubber and liquids. IX. The elastic behaviour of dry and swollen rubbers. Trans Faraday Soc. 1946;42:585-98.
23. Burton WE. Engineering with rubber. Deutch Press; 2008: p. 16-43.