[1]
D. Dowson (1979), History of tribology, 720 pages, Professional Engineering Publishing ISBN 1-86058-070-X (reprint 1998).
Google Scholar
[2]
C.A. Coulomb (1821), Théorie des machines simples, Mém. Acad. Roy. Sci. Paris Tome X, pp.161-342; new edition Hachette 2012 (in French) 368 pages, ISBN 9782012628021; Free on BNF site: gallica. bnf. fr/ark: /12148/bpt6k1095299.
Google Scholar
[3]
F.P. Bowden, D. Tabor (1950), The friction and lubrication of solids, Part I, Clarendon Press, Oxford (374 pages), ISBN 0 19 850777 1.
Google Scholar
[4]
J.F. Archard (1953), Contact and rubbing of flat surfaces, J. of Applied Physics 24, pp.981-986.
DOI: 10.1063/1.1721448
Google Scholar
[5]
M.C. Meng, K.C. Ludema (1995), Wear models and predictive equations: their form and content, Wear 181, 443-457.
DOI: 10.1016/0043-1648(95)90158-2
Google Scholar
[6]
S.C. Lim, M.F. Ashby (1987), Wear mechanism maps, Acta Metallurgica, 35, pp.1-24.
Google Scholar
[7]
P. Jost (1966) Jost Report Education and research, UK Dept. Education and Science, HMSO.
Google Scholar
[8]
M. Godet (1984) The third body approach: a mechanical view of wear Wear 100, pp.437-452.
DOI: 10.1016/0043-1648(84)90025-5
Google Scholar
[9]
J. Denape, J. Lamon (1990), Sliding friction of ceramics: mechanical action of the wear debris J. of Mat. Sci. 25, pp.3592-3604.
DOI: 10.1007/bf00575394
Google Scholar
[10]
Y. Berthier (1988), Mécanismes et tribologie. Thèse d'état es-sciences, INSA de Lyon, 156 pages.
Google Scholar
[11]
H. Czichos, S. Beker, J. Lexow (1987), Multilaboratory tribotesting: results from the Versailles Advanced Materials And Standards programme on wear test methods (VAMAS), Wear 114, pp.109-130.
DOI: 10.1016/0043-1648(87)90020-2
Google Scholar
[12]
Y. Berthier, L. Vincent And M. Godet (1992), Velocity accommodation sites and modes in tribology, Eur. J. Mech. A/solids, vol. 11, 1, pp.35-47.
Google Scholar
[13]
J. Denape, Y. Berthier, L. Vincent (2001).
Google Scholar
[14]
E. Sauger, L Ponsonnet, J. -M. Martin, L. Vincent (2000), Study of the Tribologically Transformed Structure created during fretting tests, Tribol. Intern. 33, pp.743-750.
DOI: 10.1016/s0301-679x(00)00088-8
Google Scholar
[15]
S. Descartes, Y. Berthier (2002) Rheology and flows of solid third bodies: background and application to a MoS1. 6, Wear vol. 252, pp.546-556.
DOI: 10.1016/s0043-1648(02)00008-x
Google Scholar
[16]
N. Fillot, I. Iordanoff, Y. Berthier (2005) Simulation of wear through mass balance in a dry contact, ASME Journal of Tribology, vol 127, pp.230-237.
DOI: 10.1115/1.1828437
Google Scholar
[17]
C. Boher (1992) Simulation expérimentale du comportement tribologique des matériaux prothétiques de la hanche Doctorat de l'Institut National Polytechnique de Toulouse, n° 561, 160 pages.
Google Scholar
[18]
M. Yahiaoui, J. -Y. Paris, J. Denape, A. Dourfaye (2014) Wear mechanisms of WC-Co drill bit inserts against alumina counterface under dry friction: Part 1 - WC-Co inserts with homogenous binder phase content, submitted to Wear.
DOI: 10.1016/j.ijrmhm.2014.09.018
Google Scholar
[19]
S. Fouvry, C. Paulin, S. Deyber (2009) Impact of contact size and complex gross-partial slip conditions on Ti6Al4V/Ti6Al4V fretting wear, Tribol. Intern. vol. 42, pp.461-474.
DOI: 10.1016/j.triboint.2008.08.005
Google Scholar
[20]
G. Ural, J. -Y. Paris, J. Denape, J. -D. Beguin, J. Gurt Santanach, A. Weibel, A. Peigney, Ch. Laurent, G. Chevallier, C. Estournes, Y. Paranthoen (2009).
Google Scholar
[21]
K. Delbe, S. Orozco Gomez, J. -M. Carrillo Mancuso, J. -Y. Paris, J. Denape (2012) Tribological behaviour of stellite matrix composites for high temperature applications Key Engineering Materials, vol. 498, pp.89-101.
DOI: 10.4028/www.scientific.net/kem.498.89
Google Scholar
[22]
W. Österle, I. Dörfel, C. Prietzel, H. Rooch, A. -L. Cristol-Bulthé, G. Degallaix, Y. Desplanques (2009).
DOI: 10.1016/j.wear.2008.11.023
Google Scholar