Hydrogen trap states in ultrahigh-strength AERMET 100 steel Export

@article{citeulike:1539592, abstract = {Abstract\ \ Hydrogen (H) trap states and binding energies were determined for AERMET 100 (Fe-13.4Co-11Ni-3Cr-1.2Mo-0.2C), an ultrahigh-strength steel using thermal desorption methods. Three major H desorption peaks were identified in the precipitation-hardened microstructure, associated with three distinct metallurgical trap states, and apparent activation energies for desorption were determined for each. The lattice diffusivity (D L ) associated with interstitial H was measured experimentally and verified through trapping theory to yield H-trap binding energies (E b ). Solid-solution elements in AERMET 100 reduce D L by decreasing the pre-exponential diffusion coefficient, while the activation energy for migration is similar to that of pure iron. M2C precipitates are the major reversible trap states, with E b of 11.4 to 11.6 kJ/mol and confirmed by heat treatment that eliminated these precipitates and the associated H-desorption peak. A strong trap state with E b of 61.3 to 62.2 kJ/mol is likely associated with martensite interfaces, austenite grain boundaries, and mixed dislocation cores. Undissolved metal carbides and highly misoriented grain boundaries trap H with a binding energy of 89.1 to 89.9 kJ/mol. Severe transgranular hydrogen embrittlement in peak-aged AERMET 100 at a low threshold-stress intensity is due to H repartitioning from a high density of homogeneously distributed and reversible M2C traps to the crack tip under the influence of high hydrostatic tensile stress.}, author = {Li, Daoming and Gangloff, Richard and Scully, John}, citeulike-article-id = {1539592}, citeulike-linkout-0 = {http://dx.doi.org/10.1007/s11661-004-0011-1}, day = {26}, doi = {10.1007/s11661-004-0011-1}, journal = {Metallurgical and Materials Transactions A}, keywords = {diffusion, electrochemical, hydrogen, permeation, trap}, month = {March}, number = {3}, pages = {849--864}, posted-at = {2007-08-07 11:20:32}, priority = {5}, title = {Hydrogen trap states in ultrahigh-strength AERMET 100 steel}, url = {http://dx.doi.org/10.1007/s11661-004-0011-1}, volume = {35}, year = {2004} }

TY - JOUR ID - citeulike:1539592 L3 - citeulike-article-id:1539592 N2 - Abstract  Hydrogen (H) trap states and binding energies were determined for AERMET 100 (Fe-13.4Co-11Ni-3Cr-1.2Mo-0.2C), an ultrahigh-strength steel using thermal desorption methods. Three major H desorption peaks were identified in the precipitation-hardened microstructure, associated with three distinct metallurgical trap states, and apparent activation energies for desorption were determined for each. The lattice diffusivity (D L ) associated with interstitial H was measured experimentally and verified through trapping theory to yield H-trap binding energies (E b ). Solid-solution elements in AERMET 100 reduce D L by decreasing the pre-exponential diffusion coefficient, while the activation energy for migration is similar to that of pure iron. M2C precipitates are the major reversible trap states, with E b of 11.4 to 11.6 kJ/mol and confirmed by heat treatment that eliminated these precipitates and the associated H-desorption peak. A strong trap state with E b of 61.3 to 62.2 kJ/mol is likely associated with martensite interfaces, austenite grain boundaries, and mixed dislocation cores. Undissolved metal carbides and highly misoriented grain boundaries trap H with a binding energy of 89.1 to 89.9 kJ/mol. Severe transgranular hydrogen embrittlement in peak-aged AERMET 100 at a low threshold-stress intensity is due to H repartitioning from a high density of homogeneously distributed and reversible M2C traps to the crack tip under the influence of high hydrostatic tensile stress. IS - 3 JF - Metallurgical and Materials Transactions A EP - 864 TI - Hydrogen trap states in ultrahigh-strength AERMET 100 steel VL - 35 SP - 849 KW - diffusion KW - electrochemical KW - hydrogen KW - permeation KW - trap AU - Li, Daoming AU - Gangloff, Richard AU - Scully, John PY - 2004/03/26/ UR - http://dx.doi.org/10.1007/s11661-004-0011-1 ER -