Materials Science and Technology: A Comprehensive TreatmentRobert W. Cahn, Brian R. T. Frost, Peter Haasen, Edward J. Kramer Corrosion and corrosion protection is one of most important topics in applied materials science. Corrosion science is not only important from an economic point of view, but, due to its interdisciplinary nature combining metallurgy, materials physics and electrochemistry, it is also of high scientific interest. Nowadays corrosion science even gets new impetus from surface science and polymer chemistry. This two-volume reference work belonging to the well renown series Materials Science and Tehcnology provides the reader with a sound and broad survey on the whole subject - from the fundamentals to the latest research results. Written by a team of international top-experts it will become an indispensable reference for any materials scientist, physicist or chemist involved in corrosion science. |
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Page 280
... thermal conductivity and / or low ther- mal expansion alloys to accommodate the high heat fluxes . The alloy systems being considered are high conductivity copper alloys and refractory metal alloys of niobi- um or molybdenum . Numerous ...
... thermal conductivity and / or low ther- mal expansion alloys to accommodate the high heat fluxes . The alloy systems being considered are high conductivity copper alloys and refractory metal alloys of niobi- um or molybdenum . Numerous ...
Page 288
... thermal conductivity of irradiated H - 451 graphite is shown in Fig . 10-46 ( D. L. Smith et al . , 1982 ) . The degradation in conductivity occurs over the fluence range 0.1-1.0 × 1025 n / m2 , with apparent saturation at the higher ...
... thermal conductivity of irradiated H - 451 graphite is shown in Fig . 10-46 ( D. L. Smith et al . , 1982 ) . The degradation in conductivity occurs over the fluence range 0.1-1.0 × 1025 n / m2 , with apparent saturation at the higher ...
Page 305
... thermal conductivity in the same manner as fabricated porosity . It ap- pears sufficient to account for in - reactor effects on the thermal conductivity by de- creasing the porosity correction factor as a function of He swelling . No ...
... thermal conductivity in the same manner as fabricated porosity . It ap- pears sufficient to account for in - reactor effects on the thermal conductivity by de- creasing the porosity correction factor as a function of He swelling . No ...
Contents
Zirconium Alloys in Nuclear Applications | 2 |
Structural Materials | 8 |
Nuclear Waste Materials | 12 |
Copyright | |
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Materials Science and Technology: A Comprehensive Treatment Robert Wolfgang Cahn,Peter Haasen,Edward J. Kramer No preview available - 1994 |
Common terms and phrases
alloys amorphous annealing ASME ASTM ASTM-STP atoms austenitic austenitic steels behavior breeder burnup Candu carbon chemical cladding components Conf coolant core corrosion resistance Cr 1 Mo crack growth creep damage defects density diffusion displacement ductility effects embrittlement energy fabrication fatigue ferritic ferritic steels Figure fluence flux fracture mechanics fracture toughness fuel pins grain boundaries graphite heat helium high temperature HTGR hydrogen impurities increase interstitials irradiation layer loops ments microstructure mixed oxide fuel n/cm² neutron irradiation niobium NPPs nuclear observed operation oxide oxygen parameters perature phase precipitates pressure tubes pressure vessel primary Proc radiation reduced requirements sodium spike stainless steel steam stress corrosion cracking structural materials surface swelling Table tensile tests thermal tion tritium ture vacancies water chemistry water reactor yield strength Zircaloy Zr alloys Zr Nucl