Geology Reference
In-Depth Information
Louchet F, George A (1983) Dislocation mobility measurements—an essential tool for
understanding the atomic and electronic core structure of dislocations in semiconductors. J
de Phys 44(C4):51-60
Lyall KD (1965) Plastic deformation of Galena. PhD thesis, The Australian National University,
224 pp
Mahajan S (1981) The nucleation and growth of deformation twins in metallic crystals. In: Ashby
MF et al (eds) Dislocation modelling in physical systems. Pergamon Press, Oxford, pp 217-221
Martin JW (1980) Micro mechanisms in particle-hardened alloys. Cambridge University Press,
Cambridge, 201 pp
Mataré HF (1971) Defect electronics in semiconductors. Wiley, New York
McLaren AC, Fitz Gerald JD, Gerretsen J (1989) Dislocation nucleation and multiplication in
synthetic quartz: relevance to water weakening. Phys Chem Min 16:465-482
McLaren AC, Turner RG, Boland JN, Hobbs BE (1970) Dislocation structure of deformation
lamellae in synthetic quartz: a study by electron and optical microscopy. Contr Mineral Petrol
29:104-115
McLaren AC, Cook RF, Hyde ST, Tobin RC (1983) The mechanisms of the formation and
growth of water bubbles and associated dislocation loops in synthetic quartz. Phys Chem
Miner 9:79-94
McQueen HJ (1977) The production and utility of recovered dislocation substructures. Metall
Trans 8A:807-824
Means WD (1976) Stress and strain. Basic concepts of continuum mechanics for geologists.
Springer, New York, 339 pp
Mecking H (1980) Deformation of polycrystals. In: McQueen HJ et al (eds) Strength of metals
and alloys. Proceedings of ICSMAS 1979, vol 3. Pergamon Press, Toronto, pp 1573-1594
Mecking H (1981a) Strain hardening and dynamic recovery. In: Ashby MF (ed) Dislocation
modelling of physical systems. Pergamon Press, Oxford, pp 197-211
Mecking H (1981b) Low temperature deformation of polycrystals. In: Hansen N et al (ed)
Mechanisms and microstructures. Risø National Laboratory, Roskilde, Denmark, pp 73-86
Mecking H, Gottstein G (1978) Recovery and recrystallization during deformation. In: Haessner
F (ed) Recrystallization of metallic materials, 2nd edn. Dr Riederer Verlag, Stuttgart,
pp 195-222
Mitchell TE, Foxall RA, Hirsch PB (1963) Work-hardening in niobium single crystals. Phil Mag
8:1895-1920
Mitra SK, McLean D (1966) Work-hardening and recovery in creep. Proc Roy Soc (Lon)
A295:288-299
Morris MA, Martin JL (1984a) Microstructural dependence of effective stresses and activation
volumes in creep. Acta Metall 32:1609-1623
Morris MA, Martin JL (1984b) Evolution of internal stress and substructure during creep at
intermediate temperatures. Acta Metall 32:549-561
Morrison-Smith DJ (1973) A mechanical and microstructural investigation of the deformation of
synthetic quartz crystals. PhD thesis, The Australian National University, 222 pp
Mott NF (1953) A theory of work-hardening of metals. II: Flow without slip lines, recovery and
creep. Phil Mag 44:742-765
Mott NF, Nabarro FRN (1948) Dislocation theory and transient creep. In: Report of a conference
on strength of solids, held at H H Wills Physical Laboratory, Univ of Bristol, 7-9 July 1947,
London, The Physical Society, pp 1-19
Nabarro FRN (1950) Influence of grain boundaries on the plastic deformation of metals. In:
Harrison VGW (ed) Some Recent Developments in Rheology, London, United Trade Press
(for British Rheologist's Club), pp 38-52
Nabarro FRN (1967) Theory of crystal dislocations. Clarendon Press, Oxford, 821 pp. (also
Dover, New York, 1987)
Nabarro FRN (1984a) Dislocation cores in crystals with large unit cells. In: Kubin L, Castaing J
(eds) Dislocations 1984. Core structure and physical properties, Paris, Editions du CNRS,
pp 19-28
