Publications

San Marchi, Christopher W.; Jackson, Heather F.; Foulk, James W.; Karnesky, Richard A.; Somerday, Brian P.

Abstract not provided.

San Marchi, Christopher W.

Abstract not provided.

San Marchi, Christopher W.; Somerday, Brian P.

Abstract not provided.

San Marchi, Christopher W.

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Somerday, Brian P.; Jackson, Heather F.; San Marchi, Christopher W.

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Somerday, Brian P.; San Marchi, Christopher W.; Jackson, Heather F.; Lord, Anna S.; Kobos, Peter H.; Borns, David J.

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Dedrick, Daniel E.; Houf, William G.; LaChance, Jeffrey L.; San Marchi, Christopher W.; Somerday, Brian P.; Ruggles, Adam J.

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San Marchi, Christopher W.; Yang, Nancy Y.

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Somerday, Brian P.; San Marchi, Christopher W.

Abstract not provided.

American Society of Mechanical Engineers, Pressure Vessels and Piping Division (Publication) PVP

San Marchi, Christopher W.; Somerday, Brian P.; Nibur, Kevin A.; Stalheim, Douglas G.; Boggess, Todd; Jansto, Steve

Gaseous hydrogen is an alternative to petroleum-based fuels, but it is known to significantly reduce the fatigue and fracture resistance of steels. Steels are commonly used for containment and distribution of gaseous hydrogen, albeit under conservative operating conditions (i.e., large safety factors) to mitigate so-called gaseous hydrogen embrittlement. Economical methods of distributing gaseous hydrogen (such as using existing pipeline infrastructure) are necessary to make hydrogen fuel competitive with alternatives. the effects of gaseous hydrogen on fracture resistance and fatigue resistance of pipeline steels, however, has not been comprehensively evaluated and this data is necessary for structural integrity assessment in gaseous hydrogen environments. In addition, existing standardized test methods for environment assisted cracking under sustained load appear to be inadequate to characterize low-strength steels (such as pipeline steels) exposed to relevant gaseous hydrogen environments. In this study, the principles of fracture mechanics are used to compare the fracture and fatigue performance of two pipeline steels in high-purity gaseous hydrogen at two pressures: 5.5 MPa and 21 MPa. In particular, elastic-plastic fracture toughness and fatigue crack growth rates were measured using the compact tension geometry and a pressure vessel designed for testing materials while exposed to gaseous hydrogen. Copyright © 2010 by ASME.

Somerday, Brian P.; San Marchi, Christopher W.; Nibur, Kevin A.

Abstract not provided.

American Society of Mechanical Engineers, Pressure Vessels and Piping Division (Publication) PVP

Nibur, Kevin A.; San Marchi, Christopher W.; Somerday, Brian P.

Fatigue crack growth rates and rising displacement fracture thresholds have been measured for a 4130X steel in 45 MPa hydrogen gas. the ratio of minimum to maximum load (R-ratio) and cyclic frequency was varied to assess the effects of these variables on fatigue crack growth rates. Decreasing frequency and increasing R were both found to increase crack growth rate, however, these variables are not independent of each other. Changing frequency from 0.1 Hz to 1 Hz reduced crack growth rates at R = 0.5, but had no effect at R = 0.1. When applied to a design life calculation for a steel pressure vessel consistent with a typical hydrogen trailer tube, the measured fatigue and fracture data predicted a re-inspection interval of nearly 29 years, consistent with the excellent service history of such vessels which have been in use for many years. Copyright © 2010 by ASME.

Nuclear Instruments and Methods in Physics Research B

Kolasinski, Robert K.; Whaley, Josh A.; Karnesky, Richard A.; San Marchi, Christopher W.

Abstract not provided.

Somerday, Brian P.; San Marchi, Christopher W.; Nibur, Kevin A.

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Michael, Joseph R.; San Marchi, Christopher W.

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Somerday, Brian P.; San Marchi, Christopher W.; Foulk, James W.

Threshold stress intensity factors were measured in high-pressure hydrogen gas for a variety of low alloy ferritic steels using both constant crack opening displacement and rising crack opening displacement procedures. The sustained load cracking procedures are generally consistent with those in ASME Article KD-10 of Section VIII Division 3 of the Boiler and Pressure Vessel Code, which was recently published to guide design of high-pressure hydrogen vessels. Three definitions of threshold were established for the two test methods: K{sub THi}* is the maximum applied stress intensity factor for which no crack extension was observed under constant displacement; K{sub THa} is the stress intensity factor at the arrest position for a crack that extended under constant displacement; and K{sub JH} is the stress intensity factor at the onset of crack extension under rising displacement. The apparent crack initiation threshold under constant displacement, K{sub THi}*, and the crack arrest threshold, K{sub THa}, were both found to be non-conservative due to the hydrogen exposure and crack-tip deformation histories associated with typical procedures for sustained-load cracking tests under constant displacement. In contrast, K{sub JH}, which is measured under concurrent rising displacement and hydrogen gas exposure, provides a more conservative hydrogen-assisted fracture threshold that is relevant to structural components in which sub-critical crack extension is driven by internal hydrogen gas pressure.

Somerday, Brian P.; San Marchi, Christopher W.; Nibur, Kevin A.

Abstract not provided.

Antoun, Bonnie R.; Chiesa, Michael L.; O'Connor, Devin T.; Yang, Nancy Y.; San Marchi, Christopher W.; Brown, Arthur B.

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San Marchi, Christopher W.; Yang, Nancy Y.

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Journal of Pressure Vessel Technology, Transactions of the ASME

San Marchi, Christopher W.; Balch, Dorian K.; Nibur, K.; Somerday, Brian P.

Applications requiring the containment and transportation of hydrogen gas at pressures greater than 70 MPa are anticipated in the evolving hydrogen economy infrastructure. Since hydrogen is known to alter the mechanical properties of materials, data are needed to guide the selection of materials for structural components. The objective of this study is to characterize the role of yield strength, microstructural orientation, and small concentrations of ferrite on hydrogen-assisted fracture in two austenitic stainless steels: 21Cr-6Ni-9Mn (21-6-9) and 22Cr-13Ni-SMn (22-13-5). The testing methodology involves exposure of tensile specimens to high-pressure hydrogen gas at elevated temperature in order to precharge the specimens with hydrogen, and subsequently testing the specimens in laboratory air to measure strength and ductility. In all cases, the alloys remain ductile despite precharging to hydrogen concentrations of ∼1 at. %, as demonstrated by reduction in area values between 30% and 60% and fracture modes dominated by microvoid processes. Low concentrations of ferrite and moderate increases in yield strength do not exacerbate hydrogen-assisted fracture in 21-6-9 and 22-13-5, respectively. Microstructural orientation has a pronounced effect on ductility in 22-13-5 due to the presence of aligned second-phase particles. Copyright © 2008 by ASME.

Somerday, Brian P.; San Marchi, Christopher W.

Abstract not provided.

San Marchi, Christopher W.; Somerday, Brian P.

Abstract not provided.

San Marchi, Christopher W.; Somerday, Brian P.

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San Marchi, Christopher W.; Somerday, Brian P.; Nibur, Kevin A.; Yip, Mien Y.

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San Marchi, Christopher W.; Somerday, Brian P.

Abstract not provided.