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008 170606s2017 enka sb 001 0 eng d;

010 a| 2017944822;

020 a| 9781848213753q| (hardcover);

020 a| 1848213751q| (hardcover);

035 a| (WaSeSS)ssj0002271591;

042 a| lccopycat;

049 a| EREEa| NEHH;

050 00 a| QD945b| .F695 2017;

082 04 a| 620.1126;

100 1 a| Fressengeas, Claude.?| UNAUTHORIZED;

245 10 a| Mechanics of dislocation fieldsh| [electronic resource] /c| Claude Fressengeas.;

300 a| xxi, 218 pages :b| illustrations ;c| 25 cm;

504 a| Includes bibliographical references (pages 203-215) and index.;

505 00 g| Ch. 1t| Continuous Dislocation Modeling --g| 1.1.t| Introduction --g| 1.2.t| Lattice incompatibility --g| 1.3.t| Burgers vector --g| 1.4.t| Compatibility conditions --g| 1.5.t| Dislocation fields --g| 1.6.t| Tangential continuity at interfaces --g| 1.7.t| Curvatures and rotational incompatibiliy --g| 1.8.t| Incompatibility tensor --g| 1.9.t| Conclusion --g| 1.10.t| Problems --g| 1.10.1.t| Discrete versus continuous modeling of crystal defects --g| 1.10.2.t| Incompatibility in simple shear --g| 1.10.3.t| Frank's relation --g| 1.11.t| Solutions --g| 1.11.1.t| Discrete versus continuous modeling of crystal defects --g| 1.11.2.t| Incompatibility in simple shear --g| 1.11.3.t| Frank's relation --g| ch. 2t| Elasto-static Field Equations --g| 2.1.t| Introduction --g| 2.2.t| Elasto-static solution to field equations --g| 2.2.1.t| Stokes-Helmholtz decomposition and Poisson-type equations --g| 2.2.2.t| Navier-type equations for compatible elastic distortion fields --g| 2.3.t| Straight screw dislocation in a linear isotropic elastic medium --g| 2.4.t| Straight edge dislocation in a linear isotropic elastic medium --g| 2.5.t| Conclusion --g| 2.6.t| Problems --g| 2.6.1.t| Screw dislocation --g| 2.6.2.t| Twist boundary --g| 2.6.3.t| Tilt boundary --g| 2.6.4.t| Zero-stress everywhere dislocation fields --g| 2.7.t| Solutions --g| 2.7.1.t| Screw dislocation --g| 2.7.2.t| Twist boundary --g| 2.7.3.t| Tilt boundary --g| 2.7.4.t| Zero-stress everywhere dislocation fields --g| ch. 3t| Dislocation Transport --g| 3.1.t| Introduction --g| 3.2.t| Dislocation flux and plastic distortion rate --g| 3.3.t| Coarse graining --g| 3.4.t| Compatibility versus incompatibility of plasticity --g| 3.5.t| Tangential continuity of plastic distortion rate --g| 3.6.t| Transport equations --g| 3.6.1.t| Small transformations --g| 3.6.2.t| Finite transformations --g| 3.7.t| Transport waves --g| 3.7.1.t| Annihilation --g| 3.7.2.t| Expansion of dislocation loops --g| 3.7.3.t| Initiation of a Frank -- Read source --g| 3.8.t| Numerical algorithms for dislocation transport --g| 3.9.t| Conclusion --g| 3.10.t| Problems --g| 3.10.1.t| Propagation of a discontinuous dislocation density --g| 3.10.2.t| Dislocation loop expansion --g| 3.10.3.t| Stability / instability of homogeneous dislocation distributions --g| 3.10.4.t| Dislocation nucleation --g| 3.11.t| Solutions --g| 3.11.1.t| Propagation of a discontinuous dislocation density --g| 3.11.2.t| Expansion of dislocation loops --g| 3.11.3.t| Stability / instability of homogeneous dislocation distributions --g| 3.11.4.t| Dislocation nucleation --g| ch. 4t| Constitutive Relations --g| 4.1.t| Introduction --g| 4.2.t| Dissipation --g| 4.3.t| Pressure independence --g| 4.4.t| Dislocation climb versus dislocation glide --g| 4.5.t| Viscoplastic relationships --g| 4.6.t| Coarse graining --g| 4.7.t| Contact with conventional crystal plasticity --g| ch. 5t| Elasto-plastic Field Equations --g| 5.1.t| Introduction --g| 5.2.t| Fundamental field equations --g| 5.3.t| Boundary conditions --g| 5.4.t| Coarse graining --g| 5.5.t| Resolution algorithm --g| 5.6.t| Reduced field equations --g| 5.6.1.t| Plane dislocations --g| 5.7.t| Augmented crystal plasticity --g| 5.8.t| Dynamics of a twist boundary --g| 5.9.t| Conclusion --g| 5.10.t| Problems --g| 5.10.1.t| Helical dislocations --g| 5.11.t| Solutions --g| 5.11.1.t| Helical dislocations --g| ch. 6t| Case Studies --g| 6.1.t| Introduction --g| 6.2.t| Dislocation core structure --g| 6.3.t| Piezoelectricity and dislocations --g| 6.3.1.t| Coupling piezoelectricity, lattice incompatibility and transport --g| 6.3.2.t| Piezoelectric polarization and dislocations in GaN layers --g| 6.3.3.t| Dislocation transport and electric displacement in GaN layers --g| 6.4.t| Intermittent plasticity --g| 6.5.t| Effects of size on mechanical response --g| 6.6.t| Complex loading paths --g| 6.7.t| Strain localization --g| 6.7.1.t| Experimental data in Al -- Cu -- Li alloys --g| 6.7.2.t| Simulation results --g| ch. 7t| Review and Conclusions --g| 7.1.t| Comparisons with conventional crystal plasticity --g| 7.2.t| Alternative approaches --g| 7.2.1.t| Peierls-Nabarro model --g| 7.2.2.t| Atomistic simulations --g| 7.2.3.t| Phase field methods --g| 7.2.4.t| Discrete dislocation dynamics --g| 7.3.t| Shortcomings and extensions --g| 7.3.1.t| Fracture and disconnections --g| 7.3.2.t| Rotational incompatibility and disclinations --g| 7.3.3.t| Phase transformation and generalized disclinations --g| 7.4.t| Final remarks.;

506 a| Available only to authorized users.;

538 a| Mode of access: World Wide Web;

650 0 a| Dislocations in crystals.=| ^A17133;

650 6 a| Dislocations dans les cristaux.;

650 7 a| Dislocations in crystals.2| fast0| (OCoLC)fst00895269;

650 7 a| Dislocations dans les cristaux.2| ram;

650 7 a| Matièrex| Structure.2| ram;

650 7 a| Polycristaux.2| ram;

655 0 a| Electronic books.=| ^A491897;

856 40 z| Full text available from Ebook Central - Academic Completeu| https://ebookcentral.proquest.com/lib/eastcarolina/detail.action?docID=5061568;

947 a| (OCoLC)on1018406377;

949 a| CLICK ON WEB ADDRESSw| ASISh| JOYNER188;

949 a| CLICK ON WEB ADDRESSw| ASISh| HSL77;

949 a| CLICK ON WEB ADDRESSw| ASISh| JMUSIC60;

596 a| 1 3 4;

998 a| 5322724;

999 a| CLICK ON WEB ADDRESSw| ASISc| 1i| 5322724-1001l| JNETm| JOYNERr| Ys| Yt| JNESSBKu| 5/15/2020x| EBOOKz| JERESOURCE;

999 a| CLICK ON WEB ADDRESSw| ASISc| 1i| 5322724-2001l| HSLELECm| HSLr| Ys| Yt| HEBKu| 5/15/2020x| EBOOKz| HERESOURCE;

999 a| CLICK ON WEB ADDRESSw| ASISc| 1i| 5322724-3001l| MNETm| JMUSICr| Ys| Yt| MNESSBKu| 5/15/2020x| EBOOKz| JERESOURCE;

Mechanics of dislocation fields / Claude Fressengeas.

Author/creator	Fressengeas, Claude
Format	Electronic
Publication Info	London, UK : ISTE, Ltd. ; Hoboken, NJ : Wiley, 2017.
Description	xxi, 218 pages : illustrations ; 25 cm
Supplemental Content	Full text available from Ebook Central - Academic Complete
Subjects	Dislocations in crystals. Dislocations dans les cristaux.

Contents	Ch. 1 Continuous Dislocation Modeling -- 1.1. Introduction -- 1.2. Lattice incompatibility -- 1.3. Burgers vector -- 1.4. Compatibility conditions -- 1.5. Dislocation fields -- 1.6. Tangential continuity at interfaces -- 1.7. Curvatures and rotational incompatibiliy -- 1.8. Incompatibility tensor -- 1.9. Conclusion -- 1.10. Problems -- 1.10.1. Discrete versus continuous modeling of crystal defects -- 1.10.2. Incompatibility in simple shear -- 1.10.3. Frank's relation -- 1.11. Solutions -- 1.11.1. Discrete versus continuous modeling of crystal defects -- 1.11.2. Incompatibility in simple shear -- 1.11.3. Frank's relation -- ch. 2 Elasto-static Field Equations -- 2.1. Introduction -- 2.2. Elasto-static solution to field equations -- 2.2.1. Stokes-Helmholtz decomposition and Poisson-type equations -- 2.2.2. Navier-type equations for compatible elastic distortion fields -- 2.3. Straight screw dislocation in a linear isotropic elastic medium -- 2.4. Straight edge dislocation in a linear isotropic elastic medium -- 2.5. Conclusion -- 2.6. Problems -- 2.6.1. Screw dislocation -- 2.6.2. Twist boundary -- 2.6.3. Tilt boundary -- 2.6.4. Zero-stress everywhere dislocation fields -- 2.7. Solutions -- 2.7.1. Screw dislocation -- 2.7.2. Twist boundary -- 2.7.3. Tilt boundary -- 2.7.4. Zero-stress everywhere dislocation fields -- ch. 3 Dislocation Transport -- 3.1. Introduction -- 3.2. Dislocation flux and plastic distortion rate -- 3.3. Coarse graining -- 3.4. Compatibility versus incompatibility of plasticity -- 3.5. Tangential continuity of plastic distortion rate -- 3.6. Transport equations -- 3.6.1. Small transformations -- 3.6.2. Finite transformations -- 3.7. Transport waves -- 3.7.1. Annihilation -- 3.7.2. Expansion of dislocation loops -- 3.7.3. Initiation of a Frank -- Read source -- 3.8. Numerical algorithms for dislocation transport -- 3.9. Conclusion -- 3.10. Problems -- 3.10.1. Propagation of a discontinuous dislocation density -- 3.10.2. Dislocation loop expansion -- 3.10.3. Stability / instability of homogeneous dislocation distributions -- 3.10.4. Dislocation nucleation -- 3.11. Solutions -- 3.11.1. Propagation of a discontinuous dislocation density -- 3.11.2. Expansion of dislocation loops -- 3.11.3. Stability / instability of homogeneous dislocation distributions -- 3.11.4. Dislocation nucleation -- ch. 4 Constitutive Relations -- 4.1. Introduction -- 4.2. Dissipation -- 4.3. Pressure independence -- 4.4. Dislocation climb versus dislocation glide -- 4.5. Viscoplastic relationships -- 4.6. Coarse graining -- 4.7. Contact with conventional crystal plasticity -- ch. 5 Elasto-plastic Field Equations -- 5.1. Introduction -- 5.2. Fundamental field equations -- 5.3. Boundary conditions -- 5.4. Coarse graining -- 5.5. Resolution algorithm -- 5.6. Reduced field equations -- 5.6.1. Plane dislocations -- 5.7. Augmented crystal plasticity -- 5.8. Dynamics of a twist boundary -- 5.9. Conclusion -- 5.10. Problems -- 5.10.1. Helical dislocations -- 5.11. Solutions -- 5.11.1. Helical dislocations -- ch. 6 Case Studies -- 6.1. Introduction -- 6.2. Dislocation core structure -- 6.3. Piezoelectricity and dislocations -- 6.3.1. Coupling piezoelectricity, lattice incompatibility and transport -- 6.3.2. Piezoelectric polarization and dislocations in GaN layers -- 6.3.3. Dislocation transport and electric displacement in GaN layers -- 6.4. Intermittent plasticity -- 6.5. Effects of size on mechanical response -- 6.6. Complex loading paths -- 6.7. Strain localization -- 6.7.1. Experimental data in Al -- Cu -- Li alloys -- 6.7.2. Simulation results -- ch. 7 Review and Conclusions -- 7.1. Comparisons with conventional crystal plasticity -- 7.2. Alternative approaches -- 7.2.1. Peierls-Nabarro model -- 7.2.2. Atomistic simulations -- 7.2.3. Phase field methods -- 7.2.4. Discrete dislocation dynamics -- 7.3. Shortcomings and extensions -- 7.3.1. Fracture and disconnections -- 7.3.2. Rotational incompatibility and disclinations -- 7.3.3. Phase transformation and generalized disclinations -- 7.4. Final remarks.
Bibliography note	Includes bibliographical references (pages 203-215) and index.
Access restriction	Available only to authorized users.
Technical details	Mode of access: World Wide Web
Genre/form	Electronic books.
LCCN	2017944822
ISBN	9781848213753 (hardcover)
ISBN	1848213751 (hardcover)

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