000			02080nam a2200301 a 4500
005			20250918162045.0
008			120516s2010 enka b 000 0 eng
020			_a9780521194891 (hbk.) _cRM275.29
020			_a052119489X (hbk.)
039		9	_a201205230753 _bzabidah _y05-16-2012 _zmazarita
040			_aDLC _dUKM
090			_aTA409.W454 3
090			_aTA409 _b.W454 3
100	1		_aWei, Robert Peh-ying, _d1931-
245	1	0	_aFracture mechanics : _bintegration of mechanics, materials science, and chemistry / _cRobert P. Wei.
260			_aCambridge [England] : _bCambridge University Press, _c2010.
300			_axv, 214 p. : _bill. ; _c26 cm.
504			_aIncludes bibliographical references.
520			_a'Fracture and'slow' crack growth reflect the response of a material (i.e., its microstructure) to the conjoint actions of mechanical and chemical driving forces and are affected by temperature. There is therefore a need for quantitative understanding and modeling of the influences of chemical and thermal environments and of microstructure, in terms of the key internal and external variables, and for their incorporation into design and probabilistic implications. This text, which the author has used in a fracture mechanics course for advanced undergraduate and graduate students, is based on the work of the author's Lehigh University team whose integrative research combined fracture mechanics, surface and electrochemistry, materials science, and probability and statistics to address a range of fracture safety and durability issues on aluminum, ferrous, nickel, and titanium alloys and ceramics. Examples are included to highlight the approach and applicability of the findings in practical durability and reliability problems'--Provided by publisher.
650		0	_aFracture mechanics.
907			_a.b15365190 _b2019-11-12 _c2019-11-12
942			_c01 _n0 _kTA409.W454 3
914			_avtls003500957
990			_aza
991			_aFakulti Kejuruteraan dan Alam Bina
998			_al _b2012-03-05 _cm _da _feng _genk _y0 _z.b15365190
999			_c520227 _d520227