Publications

Voth, Thomas E.; Mosso, Stewart J.; Kramer, Richard M.; Luchini, Christopher B.; Niederhaus, John H.

Abstract not provided.

Voth, Thomas E.; Sanchez, Jason J.; Mosso, Stewart J.; Kramer, Richard M.

Abstract not provided.

Voth, Thomas E.; Mosso, Stewart J.; Sanchez, Jason J.

Abstract not provided.

Mosso, Stewart J.; Kramer, Richard M.; Voth, Thomas E.

Abstract not provided.

Voth, Thomas E.; Sanchez, Jason J.; Mosso, Stewart J.; Kramer, Richard M.

Abstract not provided.

Robinson, Allen C.; Petney, Sharon P.; Drake, Richard R.; Weirs, Vincent G.; Adams, Brian M.; Vigil, Dena V.; Carpenter, John H.; Garasi, Christopher J.; Wong, Michael K.; Robbins, Joshua R.; Siefert, Christopher S.; Strack, Otto E.; Wills, Ann E.; Trucano, Timothy G.; Bochev, Pavel B.; Summers, Randall M.; Stewart, James R.; Ober, Curtis C.; Rider, William J.; Haill, Thomas A.; Lemke, Raymond W.; Cochrane, Kyle C.; Desjarlais, Michael P.; Love, Edward L.; Voth, Thomas E.; Mosso, Stewart J.; Niederhaus, John H.

Abstract not provided.

Mosso, Stewart J.; Kramer, Richard M.; Voth, Thomas E.

Abstract not provided.

Mosso, Stewart J.; Voth, Thomas E.

Abstract not provided.

Mosso, Stewart J.; Voth, Thomas E.

Abstract not provided.

Niederhaus, John H.; Voth, Thomas E.; Mosso, Stewart J.

Abstract not provided.

Niederhaus, John H.; Voth, Thomas E.; Mosso, Stewart J.

Abstract not provided.

Voth, Thomas E.; Mosso, Stewart J.; Niederhaus, John H.

Abstract not provided.

Niederhaus, John H.; Voth, Thomas E.; Mosso, Stewart J.

Abstract not provided.

Rider, William J.; Love, Edward L.; Voth, Thomas E.; Mosso, Stewart J.; Niederhaus, John H.; Strack, Otto E.; Robinson, Allen C.

Abstract not provided.

Computer Methods in Applied Mechanics and Engineering

Voth, Thomas E.; Mosso, Stewart J.; Robbins, Joshua R.

Here, we examine the coupling of the patterned-interface-reconstruction (PIR) algorithm with the extended finite element method (X-FEM) for general multi-material problems over structured and unstructured meshes. The coupled method offers the advantages of allowing for local, element-based reconstructions of the interface, and facilitates the imposition of discrete conservation laws. Of particular note is the use of an interface representation that is volume-of-fluid based, giving rise to a segmented interface representation that is not continuous across element boundaries. In conjunction with such a representation, we employ enrichment with the ridge function for treating material interfaces and an analog to Heaviside enrichment for treating free surfaces. We examine a series of benchmark problems that quantify the convergence aspects of the coupled method and examine the sensitivity to noise in the interface reconstruction. Finally, the fidelity of a remapping strategy is also examined for a moving interface problem.

Robinson, Allen C.; Mosso, Stewart J.; Siefert, Christopher S.; Hu, Jonathan J.

Abstract not provided.