List of Publications

Non-INL Research using MOOSE

  1. Stephen M Bajorek. The us nuclear regulatory commission approach to modeling and simulation of advanced non-lwrs; preparing for the next nuclear renaissance.[BibTeX]
  2. Guojun Hu, Guanheng Zhang, and Rui Hu. Reactivity feedback modeling in sam. Technical Report, Argonne National Lab.(ANL), Argonne, IL (United States), 2019.[BibTeX]
  3. G Hu, R Hu, and L Zou. Development of heat pipe reactor modeling in sam. Technical Report, Argonne National Lab.(ANL), Argonne, IL (United States), 2019.[BibTeX]
  4. Rui Hu. Three-dimensional flow model development for thermal mixing and stratification modeling in reactor system transients analyses. Nuclear Engineering and Design, 345:209–215, 2019.[BibTeX]
  5. Florian Konrad, Alexandros Savvatis, Florian Wellmann, and Kai Zosseder. Hydraulic behavior of fault zones in pump tests of geothermal wells: a parametric analysis using numerical simulations for the upper jurassic aquifer of the north alpine foreland basin. Geothermal Energy, 7(1):25, 2019.[BibTeX]
  6. Yinbin Miao, Nicolas Stauff, Aaron Oaks, Abdellatif M Yacout, and Taek K Kim. Fuel performance evaluation of annular metallic fuels for an advanced fast reactor concept. Nuclear Engineering and Design, 352:110157, 2019.[BibTeX]
  7. I Luk'yanchuk, Y Tikhonov, A Razumnaya, and VM Vinokur. Hopfions emerge in ferroelectrics. arXiv preprint arXiv:1907.03866, 2019.[BibTeX]
  8. Shengyan Shang, Yanfeng Wang, Yunpeng Wang, Haitao Ma, and Anil Kunwar. Enhancement of hardness of bulk solder by doping cu nanoparticles at the interface of sn/cu solder joint. Microelectronic Engineering, 208:47–53, 2019.[BibTeX]
  9. Jun-li Lin and Brent J Heuser. Modeling hydrogen solvus in zirconium solution by the mesoscale phase-field modeling code hyrax. Computational Materials Science, 156:224–231, 2019.[BibTeX]
  10. Jaron P Senecal and Wei Ji. Characterization of the proper generalized decomposition method for fixed-source diffusion problems. Annals of Nuclear Energy, 126:68–83, 2019.[BibTeX]
  11. Daopei Zhu, John Mangeri, Ruolin Wang, and Serge Nakhmanson. Size, shape, and orientation dependence of the field-induced behavior in ferroelectric nanoparticles. Journal of Applied Physics, 125(13):134102, 2019.[BibTeX]
  12. Jessica Freymark, Judith Bott, Mauro Cacace, Moritz Ziegler, and Magdalena Scheck-Wenderoth. Influence of the main border faults on the 3d hydraulic field of the central upper rhine graben. Geofluids, 2019.[BibTeX]
  13. C Peco, Y Liu, C Rhea, and JE Dolbow. Models and simulations of surfactant-driven fracture in particle rafts. International Journal of Solids and Structures, 156:194–209, 2019.[BibTeX]
  14. Lukasz Kuna, John Mangeri, Edward P Gorzkowski, James A Wollmershauser, and Serge Nakhmanson. Mesoscale modeling of polycrystalline light transmission. Acta Materialia, 2019.[BibTeX]
  15. John F Sevic and Nobuhiko P Kobayashi. A computational phase field study of conducting channel formation in dielectric thin films: a view toward the physical origins of resistive switching. Journal of Applied Physics, 126(6):065305, 2019.[BibTeX]
  16. Daniel Z Huang, P-O Persson, and Matthew J Zahr. High-order, linearly stable, partitioned solvers for general multiphysics problems based on implicit–explicit runge–kutta schemes. Computer Methods in Applied Mechanics and Engineering, 346:674–706, 2019.[BibTeX]
  17. Zijian Hong and Venkatasubramanian Viswanathan. Prospect of thermal shock induced healing of lithium dendrite. ACS Energy Letters, 4(5):1012–1019, 2019.[BibTeX]
  18. I Luk'yanchuk, Y Tikhonov, A Sené, A Razumnaya, and VM Vinokur. Harnessing ferroelectric domains for negative capacitance. Communications Physics, 2(1):22, 2019.[BibTeX]
  19. Elyas Goli, Ian D Robertson, Harshit Agarwal, Emmy L Pruitt, Joshua M Grolman, Philippe H Geubelle, and Jeffrey S Moore. Frontal polymerization accelerated by continuous conductive elements. Journal of Applied Polymer Science, 136(17):47418, 2019.[BibTeX]
  20. Philipp Schädle, Patrick Zulian, Daniel Vogler, R Sthavishtha Bhopalam, Maria GC Nestola, Anozie Ebigbo, Rolf Krause, and Martin O Saar. 3d non-conforming mesh model for flow in fractured porous media using lagrange multipliers. Computers & Geosciences, 2019.[BibTeX]
  21. Reeju Pokharel, Anirban Patra, Donald W Brown, Bjørn Clausen, Sven C Vogel, and George T Gray III. An analysis of phase stresses in additively manufactured 304l stainless steel using neutron diffraction measurements and crystal plasticity finite element simulations. International Journal of Plasticity, 2019.[BibTeX]
  22. Austin P Ladshaw, Alexander I Wiechert, Amy K Welty, Kevin L Lyon, Jack D Law, Robert T Jubin, Costas Tsouris, and Sotira Yiacoumi. Adsorbents and adsorption models for capture of kr and xe gas mixtures in fixed-bed columns. Chemical Engineering Journal, pages 122073, 2019.[BibTeX]
  23. Zeeshan Ahmad, Zijian Hong, and Venkatasubramanian Viswanathan. Dendrite suppression of metal electrodeposition with liquid crystalline electrolytes. arXiv preprint arXiv:1907.04441, 2019.[BibTeX]
  24. Yingjie Liu, Christian Peco, and John Dolbow. A fully coupled mixed finite element method for surfactants spreading on thin liquid films. Computer Methods in Applied Mechanics and Engineering, 345:429–453, 2019.[BibTeX]
  25. Boris Boutkov and others. Geometric Multigrid for Unstructured Finite Elements: Implementation and Applications. PhD thesis, State University of New York at Buffalo, 2019.[BibTeX]
  26. Robert A Lefebvre, C Permann, Brandon R Langley, Bradley T Rearden, and Richard C Martineau. Moose integration in the neams workbench. Technical Report, Oak Ridge National Lab.(ORNL), Oak Ridge, TN (United States), 2018.[BibTeX]
  27. MC Messner and T-L Sham. Detection of ratcheting in finite element calculations. In ASME 2018 Pressure Vessels and Piping Conference, V01BT01A013–V01BT01A013. American Society of Mechanical Engineers, 2018.[BibTeX]
  28. Srdjan Simunovic, Jake Mcmurray, Theodore M Besmann, Emily Moore, and Markus Piro. Coupled mass and heat transport models for nuclear fuels using thermodynamic calculations. Technical Report, Oak Ridge National Lab.(ORNL), Oak Ridge, TN (United States), 2018.[BibTeX]
  29. Kevin J Dugan, Shane W Hart, and Bradley T Rearden. Warthog: coupling nek5000 thermal hydraulics to bison fuel performance through the giraffe interface. Technical Report, Oak Ridge National Lab.(ORNL), Oak Ridge, TN (United States), 2018.[BibTeX]
  30. Shane Keniley and Davide Curreli. Crane: a moose-based open source tool for plasma chemistry applications. arXiv preprint arXiv:1905.10004, 2019.[BibTeX]
  31. Jaron P Senecal. Efficient Coupling Algorithms and Reduced-Order Methods for High-Fidelity Multiphysics Simulations of Nuclear Reactors. PhD thesis, Rensselaer Polytechnic Institute, 2018.[BibTeX]
  32. Andrew F Dykhuis and Michael P Short. Phase field modeling of irradiation-enhanced corrosion of zircaloy-4 in pwrs. Corrosion Science, 146:179–191, 2019.[BibTeX]
  33. J.-L. Lin. Investigation [of] effect of external stress on hydrogen solvus in a Zircaloy-4 fuel cladding alloy: Application of in situ diffraction technique and mesoscale phase-field simulation. PhD thesis, University of Illinois at Urbana-Champaign, September 2018. \url http://hdl.handle.net/2142/101497.[BibTeX]
  34. Z. Hong and V. Viswanathan. Phase-field simulations of lithium dendrite growth with open-source software. ACS Energy Letters, 3(7):1737–1743, June 2018. \url https://doi.org/10.1021/acsenergylett.8b01009.[BibTeX]
  35. H. R. Ma, A. Kunwar, S. Y. Shang, C. R. Jiang, Y. P. Wang, H. T. Ma, and N. Zhao. Evolution behavior and growth kinetics of intermetallic compounds at Sn/Cu interface during multiple reflows. Intermetallics, 96:1–12, May 2018. \url https://doi.org/10.1016/j.intermet.2018.01.022.[BibTeX]
  36. S. Shang, A. Kunwar, J. Yao, Y. Wang, N. Zhao, M. Huang, and H. Ma. All-round suppression of Cu$_6$Sn$_5$ growth in Sn/Cu joints by utilizing TiO$_2$ nanoparticles. Journal of Materials Science: Materials in Electronics, 29(18):15966–15972, September 2018. \url https://doi.org/10.1007/s10854-018-9682-z.[BibTeX]
  37. J.-L. Lin and B. J. Heuser. Modeling hydrogen solvus in zirconium solution by the mesoscale phase-field modeling code Hyrax. Computational Materials Science, 156:224–231, January 2019. \url https://doi.org/10.1016/j.commatsci.2018.09.051.[BibTeX]
  38. C. Peco, Y. Liu, C. Rhea, and J. E. Dolbow. Models and simulations of surfactant-driven fracture in particle rafts. International Journal of Solids and Structures, August 2018. \url https://doi.org/10.1016/j.ijsolstr.2018.08.014.[BibTeX]
  39. E. Peters, G. Blöcher, S. Salimzadeh, P. J. P. Egberts, and M. Cacace. Modelling of multi-lateral well geometries for geothermal applications. Advances in Geosciences, 45:209–215, August 2018. \url https://doi.org/10.5194/adgeo-45-209-2018.[BibTeX]
  40. X. Ma and A. Elbanna. Strain localization in dry sheared granular materials: A compactivity-based approach. Physical Review E, 98(2):022906 (18 pages), August 2018. \url https://doi.org/10.1103/PhysRevE.98.022906, ArXiv e-print: \url http://arxiv.org/abs/1701.03087.[BibTeX]
  41. J. Mangeri, S. P. Alpay, S. Nakhmanson, and O. G. Heinonen. Electromechanical control of polarization vortex ordering in an interacting ferroelectric-dielectric composite dimer. Applied Physics Letters, 113(9):092901 (5 pages), August 2018. \url https://doi.org/10.1063/1.5046080.[BibTeX]
  42. C. Green and J. Ennis-King. Steady flux regime during convective mixing in three-dimensional heterogeneous porous media. Fluids, 3:58 (21 pages), August 2018. \url http://dx.doi.org/10.3390/fluids3030058.[BibTeX]
  43. A. B. Jacquey, L. Urpi, M. Cacace, G. Blöcher, G. Zimmermann, and M. Scheck-Wenderoth. Far field poroelastic response of geothermal reservoirs to hydraulic stimulation treatment: Theory and application at the Groß Schönebeck geothermal research facility. International Journal of Rock Mechanics and Mining Sciences, 117:316–327, October 2018. \url https://doi.org/10.1016/j.ijrmms.2018.08.012.[BibTeX]
  44. Y. Fu, J. Michopoulos, and B. Gnanasekaran. Microstructure evolution under isothermal and continuous cooling conditions via a combined multiphase field and nucleation approach. Computational Materials Science, 155:457–465, December 2018. \url https://doi.org/10.1016/j.commatsci.2018.08.057.[BibTeX]
  45. G. I. Maldonado. Enhanced accident-tolerant fuel performance and reliability for aggressive iPWR/SMR operation. Technical Report DOE/NEUP 14-6893, Nuclear Energy University Programs (NEUP), August 2018. \url https://doi.org/10.2172/1470224.[BibTeX]
  46. K. Sood, B. Norris, and E. Jessup. Iterative solver selection techniques for sparse linear systems. In J. B. Sartor, T. D'Hondt, and W. De Meuter, editors, Proceedings of the International Conference on Parallel Processing (ICPP'18), 4 (2 pages). Eugene, Oregon, August 13–16 2018. \url http://oaciss.uoregon.edu/icpp18/publications/pos130s2-file1.pdf.[BibTeX]
  47. R. T. Sweet, A. T. Nelson, and B. D. Wirth. Analysis of FeCrAl and UO$_2$ fuel including discrete and smeared cracks, and fuel relocation. Technical Report ORNL/TM–2018/889, Oak Ridge National Laboratory, June 2018. \url https://doi.org/10.2172/1460192.[BibTeX]
  48. R. A. Freeman. Analysis of pellet-cladding mechanical interaction on U$_3$Si$_2$ fuel with a multi-layer SiC cladding using BISON. Master's thesis, University of South Carolina, 2015. \url https://tinyurl.com/ycygv735.[BibTeX]
  49. D. Pizzocri. Modelling and assessment of inert gas behaviour in UO$_2$ nuclear fuel for transient analysis. PhD thesis, Politecnico di Milano, June 2018. \url https://tinyurl.com/y6v37q6s.[BibTeX]
  50. K. Ahmed and A. El-Azab. Phase Field Modeling of Microstructure Evolution in Nuclear Materials. In W. Andreoni and S. Yip, editors, Handbook of Materials Modeling, Applications: Current and Emerging Materials, pages TBD. 2018.[BibTeX]
  51. D. Andersson. Density functional theory calculations applied to nuclear fuels. In W. Andreoni and S. Yip, editors, Handbook of Materials Modeling, Applications: Current and Emerging Materials, pages TBD. 2019.[BibTeX]
  52. B. W. Spencer, D. Schwen, and J. D. Hales. Multiphysics modeling of nuclear materials. In W. Andreoni and S. Yip, editors, Handbook of Materials Modeling, Applications: Current and Emerging Materials, pages TBD. 2019.[BibTeX]
  53. R. Gałek. Two-dimensional numerical simulation of a thermoelectric cooler module. Technical Transactions — Mechanics, 7:167–178, July 2018. \url https://doi.org/10.4467/2353737XCT.18.107.8802.[BibTeX]
  54. V. Yurkiv, A. Ramasubramanian, T. Foroozan, R. Shahbazian-Yassar, and F. Mashayek. Fundamental understanding of Solid Electrolyte Interface (SEI) effects on Li dendrite evolution: Multi-scale modeling study. Meeting Abstracts, MA2018-02(8):511, 2018. \url https://tinyurl.com/yavequvt.[BibTeX]
  55. X. Zhang and Y. Liao. A phase-field model for solid-state selective laser sintering of metallic materials. Powder Technology, August 2018. \url https://doi.org/10.1016/j.powtec.2018.08.025.[BibTeX]
  56. K. C. Pitike, J. Mangeri, H. Whitelock, T. Patel, P. Dyer, S. P. Alpay, and S. Nakhmanson. Metastable vortex-like polarization textures in ferroelectric nanoparticles of different shapes and sizes. Journal of Applied Physics, 124(6):064104 (10 pages), August 2018. \url https://doi.org/10.1063/1.5037163.[BibTeX]
  57. M. Hu and K. Regenauer-Lieb. Entropic limit analysis applied to radial cavity expansion problems. Frontiers in Materials, 5:47 (10 pages), August 2018. \url https://doi.org/10.3389/fmats.2018.00047.[BibTeX]
  58. J. Zhang. Studies of lanthanide transport in metallic fuel. Technical Report 14-6482, Nuclear Energy University Programs, The Ohio State University, April 2018. \url https://doi.org/10.2172/1432451.[BibTeX]
  59. G. Zhang and R. Hu. Development of MSR transient safety analysis capability in SAM. In Transactions of the American Nuclear Society Annual Meeting (ANS 2018), volume 118, 1053–1056. Philadelphia, Pennsylvania, June 17–21 2018. \url http://ansannual.org/wp-content/2018/Data/pdfs/444-25000.pdf.[BibTeX]
  60. K. J. Dugan and S. W. D. Hart. Warthog: At the Intersection of MOOSE and SHARP. In Transactions of the American Nuclear Society Annual Meeting (ANS 2018), volume 118, 970–972. Philadelphia, Pennsylvania, June 17–21 2018. \url http://ansannual.org/wp-content/2018/Data/pdfs/419-24572.pdf.[BibTeX]
  61. D. Andersson, M. Cooper, T. Matthews, R. Perriot, X.-Y. Liu, and C. Stanek. Atomistic simulations of point defect behavior in nuclear fuels. In Transactions of the American Nuclear Society Annual Meeting (ANS 2018), volume 118, 1328–1331. Philadelphia, Pennsylvania, June 17–21 2018. \url http://ansannual.org/wp-content/2018/Data/pdfs/534-24973.pdf.[BibTeX]
  62. L. Swiler, R. Lefebvre, B. Langley, and A. Thompson. The NEAMS Workbench and Dakota: Providing an environment for uncertainty anlayses. In Transactions of the American Nuclear Society Annual Meeting (ANS 2018), volume 118, 975–978. Philadelphia, Pennsylvania, June 17–21 2018. \url http://ansannual.org/wp-content/2018/Data/pdfs/421-24585.pdf.[BibTeX]
  63. G. Singh, J. Gorton, D. Schappel, N. R. Brown, Y. Katoh, K. Terrani, and B. D. Wirth. Preliminary analysis of SiC BWR channel box performance under normal operation. Technical Report ORNL/TM-2018/854, Oak Ridge National Laboratory, May 2018. \url https://doi.org/10.2172/1439933.[BibTeX]
  64. A. B. Jacquey. Coupled thermo-hydro-mechanical processes in geothermal reservoirs: A multiphysic and multiscale approach linking geology and 3D numerical modelling. PhD thesis, RWTH Aachen University, July 2017. \url https://doi.org/10.18154/RWTH-2017-09790.[BibTeX]
  65. Y. Yang, M. Yi, B.-X. Xu, and L.-Q. Chen. Phase-field modeling of non-isothermal grain coalescence in the unconventional sintering techniques. ArXiv e-print, June 2018. \url https://arxiv.org/abs/1806.02799.[BibTeX]
  66. G. Blöcher, M. Cacace, A. B. Jacquey, A. Zang, O. Heidbach, H. Hofmann, C. Kluge, and G. Zimmermann. Evaluating micro-seismic events triggered by reservoir operations at the geothermal site of Groß Schönebeck (Germany). Rock Mechanics and Rock Engineering, 51(10):3265–3279, October 2018. \url https://doi.org/10.1007/s00603-018-1521-2.[BibTeX]
  67. D. Schappel, K. Terrani, J. J. Powers, L. L. Snead, and B. D. Wirth. Modeling the performance of TRISO-based fully ceramic matrix (FCM) fuel in an LWR environment using BISON. Nuclear Engineering and Design, 335:116–127, August 2018. \url https://doi.org/10.1016/j.nucengdes.2018.05.018.[BibTeX]
  68. A. R. M. Iasir, N. J. Peters, and K. D. Hammond. Estimation of effective thermal conductivity in U-10Mo fuels with distributed xenon gas bubbles. Journal of Nuclear Materials, 508:159–167, September 2018. \url https://doi.org/10.1016/j.jnucmat.2018.05.032.[BibTeX]
  69. I. D. Robertson, M. Yourdkhani, P. J. Centellas, J. E. Aw, D. G. Ivanoff, E. Goli, E. M. Lloyd, L. M. Dean, N. R. Sottos, P. H. Geubelle, J. S. Moore, and S. R. White. Rapid energy-efficient manufacturing of polymers and composites via frontal polymerization. Nature, 557:223–227, May 2018. \url https://doi.org/10.1038/s41586-018-0054-x.[BibTeX]
  70. Y. Mao and L. Anand. Fracture of elastomeric materials by crosslink failure. Journal of Applied Mechanics, 85(8):081008 (14 pages), June 2018. Paper No: JAM-18-1056, \url https://tinyurl.com/ybxwq6qe.[BibTeX]
  71. E. Goli, I. D. Robertson, P. H. Geubelle, and J. S. Moore. Frontal polymerization of dicyclopentadiene: A numerical study. The Journal of Physical Chemistry B, 122(16):4583–4591, 2018. \url https://doi.org/10.1021/acs.jpcb.7b12316.[BibTeX]
  72. T. Foroozan, F. A. Soto, V. Yurkiv, S. Sharifi-Asl, R. Deivanayagam, Z. Huang, R. Rojaee, F. Mashayek, P. B. Balbuena, and R. Shahbazian-Yassar. Synergistic Effect of Graphene Oxide for Impeding the Dendritic Plating of Li. Advanced Functional Materials, 28(15):1705917 (13 pages), April 2018. \url https://doi.org/10.1002/adfm.201705917.[BibTeX]
  73. H. Wang, S. Biswas, Y. Han, and V. Tomar. A phase field modeling based study of microstructure evolution and its influence on thermal conductivity in polycrystalline tungsten under irradiation. Computational Materials Science, 150:169–179, July 2018. \url https://doi.org/10.1016/j.commatsci.2018.03.070.[BibTeX]
  74. H. Rattez, I. Stefanou, J. Sulem, M. Veveakis, and T. Poulet. The importance of thermo-hydro-mechanical couplings and microstructure to strain localization in 3D continua with application to seismic faults. Part II: Numerical implementation and post-bifurcation analysis. Journal of the Mechanics and Physics of Solids, 115:1–29, June 2018. \url https://doi.org/10.1016/j.jmps.2018.03.003.[BibTeX]
  75. Y. Mao and L. Anand. A theory for fracture of polymeric gels. Journal of the Mechanics and Physics of Solids, 115:30–53, June 2018. \url https://doi.org/10.1016/j.jmps.2018.02.008.[BibTeX]
  76. C. Bilgen, A. Kopaničáková, R. Krause, and K. Weinberg. A phase-field approach to conchoidal fracture. Meccanica, 53(6):1203–1219, April 2018. \url https://doi.org/10.1007/s11012-017-0740-z.[BibTeX]
  77. M. Ševeček, A. Gurgen, A. Seshadri, Y. Che, M. Wagih, B. Phillips, V. Champagne, and K. Shirvan. Development of Cr cold-spray coated fuel cladding with enhanced accident tolerance. Nuclear Engineering and Technology, 50(2):229–236, March 2018. \url https://doi.org/10.1016/j.net.2017.12.011.[BibTeX]
  78. M. R. Tonks, A. Cheniour, and L. Aagesen. How to apply the phase field method to model radiation damage. Computational Materials Science, 147:353–362, May 2018. \url https://doi.org/10.1016/j.commatsci.2018.02.007.[BibTeX]
  79. M. C. Teague, T. Rodgers, S. Grutzik, and S. Meserole. Characterization and modeling of microstructural stresses in alumina. Journal of the American Ceramic Society, 101(5):2155–2161, May 2018. \url https://doi.org/10.1111/jace.15369.[BibTeX]
  80. V. Yurkiv, T. Foroozan, A. Ramasubramanian, R. Shahbazian-Yassar, and F. Mashayek. Phase-field modeling of solid electrolyte interface (SEI) influence on Li dendritic behavior. Electrochimica Acta, 265:609–619, March 2018. \url https://doi.org/10.1016/j.electacta.2018.01.212.[BibTeX]
  81. J. Park, J. Mangeri, Q. Zhang, M. H. Yusuf, A. Pateras, M. Dawber, M. Holt, O. Heinonen, S. Nakhmanson, and P. G. Evans. Domain alignment within ferroelectric/dielectric PbTiO$_3$/SrTiO$_3$ superlattice nanostructures. Nanoscale, 10(7):3262–3271, February 2018. \url https://doi.org/10.1039/C7NR07203A.[BibTeX]
  82. C. Planta, D. Vogler, M. Nestola, P. Zulian, and R. Krause. Variational parallel information transfer between unstructured grids in geophysics–Applications and solutions methods. In Proceedings of the 43rd Workshop on Geothermal Reservoir Engineering. Stanford, California, February 12–14, 2018. Paper SGP-TR-213, \url https://tinyurl.com/yc48rtpe.[BibTeX]
  83. J. R. Harter, L. de Sousa Oliveira, A. Truszkowska, T. Palmer, and P. A. Greaney. Deterministic phonon transport predictions of thermal conductivity in uranium dioxide with xenon impurities. Journal of Heat Transfer, 140(5):051301 (11 pages), May 2018. Paper No. HT-16-1523, \url https://doi.org/10.1115/1.4038554.[BibTeX]
  84. Y. He, P. Chen, Y. Wu, G. H. Su, W. Tian, and S. Qiu. Preliminary evaluation of U$_3$Si$_2$-FeCrAl fuel performance in light water reactors through a multi-physics coupled way. Nuclear Engineering and Design, 328:27–35, March 2018. \url https://doi.org/10.1016/j.nucengdes.2017.12.019.[BibTeX]
  85. H. Ma, H. Ma, A. Kunwar, S. Shang, Y. Wang, J. Chen, M. Huang, and N. Zhao. Effect of initial Cu concentration on the IMC size and grain aspect ratio in Sn–xCu solders during multiple reflows. Journal of Materials Science: Materials in Electronics, 29(1):602–613, January 2018. \url https://doi.org/10.1007/s10854-017-7952-9.[BibTeX]
  86. R. T. Sweet, N. M. George, G. I. Maldonado, K. A. Terrani, and B. D. Wirth. Fuel performance simulation of iron-chrome-aluminum (FeCrAl) cladding during steady-state LWR operation. Nuclear Engineering and Design, 328:10–26, March 2018. \url https://doi.org/10.1016/j.nucengdes.2017.11.043.[BibTeX]
  87. Y. Miao, K. A. Gamble, D. Andersson, Z.-G. Mei, and A. M. Yacout. Rate theory scenarios study on fission gas behavior of U$_3$Si$_2$ under LOCA conditions in LWRs. Nuclear Engineering and Design, 326:371–382, January 2018. \url https://doi.org/10.1016/j.nucengdes.2017.11.034.[BibTeX]
  88. G. Singh, R. Sweet, N. R. Brown, B. D. Wirth, Y. Katoh, and K. Terrani. Parametric evaluation of SiC/SiC composite cladding with UO$_2$ fuel for LWR applications: Fuel rod interactions and impact of nonuniform power profile in fuel rod. Journal of Nuclear Materials, 499:155–167, February 2018. \url https://doi.org/10.1016/j.jnucmat.2017.10.059.[BibTeX]
  89. G. Singh, K. Terrani, and Y. Katoh. Thermo-mechanical assessment of full SiC/SiC composite cladding for LWR applications with sensitivity analysis. Journal of Nuclear Materials, 499:126–143, February 2018. \url https://doi.org/10.1016/j.jnucmat.2017.11.004.[BibTeX]
  90. S.-M. Lu. A global review of enhanced geothermal system (EGS). Renewable and Sustainable Energy Reviews, 81, Part 2:2902–2921, January 2018. \url https://doi.org/10.1016/j.rser.2017.06.097.[BibTeX]
  91. J. P. Senecal and W. Ji. Development of an efficient tightly coupled method for multiphysics reactor transient analysis. Progress in Nuclear Energy, 103:33–44, March 2018. \url https://doi.org/10.1016/j.pnucene.2017.10.012.[BibTeX]
  92. X. Wu, T. Kozlowski, and H. Meidani. Kriging-based inverse uncertainty quantification of nuclear fuel performance code BISON fission gas release model using time series measurement data. Reliability Engineering & System Safety, 169:422–436, January 2018. \url https://doi.org/10.1016/j.ress.2017.09.029.[BibTeX]
  93. A. Ramasubramanian, V. Yurkiv, A. Najafi, A. Khounsary, R. Shahbazian-Yassar, and F. Mashayek. A comparative study on continuum-scale modeling of elasto-plastic deformation in rechargeable ion batteries. Journal of the Electrochemical Society, 164(13):A3418–A3425, November 2017. \url https://doi.org/10.1149/2.1911713jes.[BibTeX]
  94. T. Downar. Collocation-based surrogate models for uncertainty quantification and validation of coupled, multiphysics fuel performance simulation tools. Technical Report 13-5328, Nuclear Energy University Programs, October 2017. \url https://tinyurl.com/y9ea4egw.[BibTeX]
  95. X. Wu. Metamodel-based inverse uncertainty quantification of nuclear reactor simulators under the Bayesian framework. PhD thesis, University of Illinois at Urbana-Champaign, December 2017. \url http://hdl.handle.net/2142/99335.[BibTeX]
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  185. M. Favino, S. Pozzi, S. Pezzuto, F. W. Prinzen, A. Auricchio, and R. Krause. Impact of mechanical deformation on pseudo-ECG: A simulation study. Europace, 18(suppl_4):iv77–iv84, December 2016. \url http://doi.org/10.1093/europace/euw353, Special issue for the 8th TRM Forum on Computer Simulation and Experimental Assessment of Cardiac Function: Towards Integration of Cardiac Functions, 6–8 December, 2015.[BibTeX]
  186. P. Klitzke, M. Luzi-Helbing, J. M. Schicks, M. Cacace, A. B. Jacquey, J. Sippel, M. Scheck-Wenderoth, and J. I. Faleide. Gas hydrate stability zone of the Barents Sea and Kara Sea region. Energy Procedia, 97:302–309, November 2016. \url https://doi.org/10.1016/j.egypro.2016.10.005.[BibTeX]
  187. H. Ma, A. Kunwar, B. Guo, J. Sun, C. Jiang, Y. Wang, X. Song, N. Zhao, and H. Ma. Effect of cooling condition and Ag on the growth of intermetallic compounds in Sn-based solder joints. Applied Physics A, 122(12):1052 (10 pages), December 2016. \url https://doi.org/10.1007/s00339-016-0543-4.[BibTeX]
  188. R. A. Lefebvre, B. R. Langley, and A. B. Thompson. Report on NEAMS Workbench support for MOOSE applications. Technical Report ORNL/TM–2016/572, Oak Ridge National Laboratory, September 2016. \url https://doi.org/10.2172/1328333.[BibTeX]
  189. K. Chockalingam, V. G. Kouznetsova, O. van der Sluis, and M. G. D. Geers. 2D phase field modeling of sintering of silver nanoparticles. Computer Methods in Applied Mechanics and Engineering, 312:492–508, December 2016. \url https://doi.org/10.1016/j.cma.2016.07.002.[BibTeX]
  190. J. Yoo, Y.-J. Choi, and C. L. Smith. RELAP-7 software verification and validation plan, Requirements Traceability Matrix (RTM) Part 2: Code assessment strategy, procedure, and RTM update. Technical Report INL/EXT-16-40015, Idaho National Laboratory, September 2016. \url http://tinyurl.com/hs29f2z.[BibTeX]
  191. A. B. Giorla. Simulation of concrete members affected by alkali-silica reaction with Grizzly. Technical Report ORNL/TM–2016/523, Oak Ridge National Laboratory, September 2016. \url http://tinyurl.com/jfcylda.[BibTeX]
  192. A. Kunwar, H. Ma, M. Qi, J. Sun, L. Qu, B. Guo, N. Zhao, Y. Wang, and H. Ma. Positive feedback on imposed thermal gradient by interfacial bubbles in Cu/liquid Sn-3.5Ag/Cu joints. In 17th International Conference on Electronic Packaging Technology (ICEPT), 608–611. Harbin, China, August 2016. IEEE. \url https://doi.org/10.1109/ICEPT.2016.7583207.[BibTeX]
  193. J. A. Turner, K. Clarno, M. Sieger, R. Bartlett, B. Collins, R. Pawlowski, R. Schmidt, and R. Summers. The virtual environment for reactor applications (VERA): Design and architecture. Journal of Computational Physics, 326:544–568, December 2016. \url https://doi.org/10.1016/j.jcp.2016.09.003.[BibTeX]
  194. R. Hu and Y. Yu. A computationally efficient method for full-core conjugate heat transfer modeling of sodium fast reactors. Nuclear Engineering and Design, 308:182–193, November 2016. \url https://doi.org/10.1016/j.nucengdes.2016.08.018.[BibTeX]
  195. J. Stasch, B. Avci, and P. Wriggers. Numerical simulation of fluid-structure interaction problems by a coupled SPH-FEM approach. In Proceedings of the European Congress on Computational Methods in Applied Sciences and Engineering (ECCOMAS), 8788 (1 page). Crete, Greece, June 5–10, 2016. \url http://tinyurl.com/z3jk2pw.[BibTeX]
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  199. A. Giorla, Y. Le Pape, and H. Huang. Meso-scale modeling of irradiation in pressurized water reactor concrete biological shields. In V. Saouma, J. Bolander, and E. Landis, editors, Proceedings of the 9th International Conference on Fracture Mechanics of Concrete and Concrete Structures (FraMCoS-9). Berkeley, California, May 30–June 1, 2016. Paper 238, \url https://doi.org/10.21012/FC9.238.[BibTeX]
  200. K. T. Clarno, R. Pawlowski, S. Stimpson, and J. Powers. Standalone BISON fuel performance results for Watts Bar Unit 1, cycles 1-3. Technical Report ORNL/TM–2015/776, Oak Ridge National Laboratory, March 2016. \url https://doi.org/10.2172/1248783.[BibTeX]
  201. A. Patra and C. Tome. Interfacing VPSC with finite element codes. Demonstration of irradiation growth simulation in a cladding tube. Technical Report LA-UR–16-21960, Los Alamos National Laboratory, March 2016. \url https://doi.org/10.2172/1244382.[BibTeX]
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  207. D. T. Fox, L. Guo, Y. Fujita, H. Huang, and G. Redden. Experimental and numerical analysis of parallel reactant flow and transverse mixing with mineral precipitation in homogeneous and heterogeneous porous media. Transport in Porous Media, 111(3):605–626, February 2016. \url https://doi.org/10.1007/s11242-015-0614-6.[BibTeX]
  208. T. Poulet and M. Veveakis. A viscoplastic approach for pore collapse in saturated soft rocks using REDBACK: an open-source parallel simulator for Rock mEchanics with Dissipative feedBACKs. Computers and Geotechnics, 74:211–221, April 2016. \url https://doi.org/10.1016/j.compgeo.2015.12.015.[BibTeX]
  209. M. Favino, E. Foster, S. Pezzuto, S. Pozzi, F. Prinzen, A. Auricchio, and R. Krause. Coupling strategies for electro-mechanics in the heart. In Proceedings of the Fifth Chilean Workshop on Numerical Analysis of Partial Differential Equations (WONAPDE2016). Concepción, Chile, January 11–15, 2016. \url http://tinyurl.com/ybvp9lge.[BibTeX]
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  211. L. L. Tavlarides, R. Lin, Y. Nan, S. Yiacoumi, C. Tsouris, A. Ladshaw, K. Sharma, J. Gabitto, and D. DePaoli. Sorption modeling and verification for off-gas treatment. Technical Report DOE/NEUP-11-3175, Nuclear Energy University Programs (NEUP), April 2015. Project 11-3175, \url https://doi.org/10.2172/1179788.[BibTeX]
  212. M. Rose, T. J. Downar, X. Wu, and T. Kozlowski. Evaluation of accident tolerant FeCrAl coating for PWR cladding under normal operating conditions with coupled neutron transport and fuel performance. In Proceedings of the Joint International Conference on Mathematics and Computation (M&C), Supercomputing in Nuclear Applications (SNA), and the Monte Carlo (MC) Method. Nashville, Tennessee, April 19–23, 2015. \url https://tinyurl.com/y99uvrl4.[BibTeX]
  213. K. E. Ahmed. Phase field modeling of grain growth in porous polycrystalline solids. PhD thesis, Purdue University, December 2015. \url https://docs.lib.purdue.edu/dissertations/AAI10090207/.[BibTeX]
  214. T. Poulet, P. Schaubs, P. K. Rachakonda, G. Douglas, D. Lester, G. Metcalfe, H. A. Sheldon, R. Tung, L. Reid, K. Regenauer-Lieb, and M. Trefry. The CSIRO groundwater cooling project – Cooling Australia's latest supercomputer with groundwater. In Proceedings of the World Geothermal Congress. Melbourne, Australia, April 19–25, 2015. \url https://tinyurl.com/yc258yta.[BibTeX]
  215. Z. Zhang. Finite element methods for interface problems with mesh adaptivity. PhD thesis, Duke University, December 2015. \url http://tinyurl.com/z52to4j.[BibTeX]
  216. J. J. Powers. Early implementation of SiC cladding fuel performance models in BISON. Technical Report ORNL/TM-2015/452, Oak Ridge National Laboratory, September 2015. \url https://doi.org/10.2172/1215605.[BibTeX]
  217. N. George, R. Sweet, G. I. Maldonado, B. D. Wirth, J. J. Powers, and A. Worrall. Fuel performance calculations for FeCrAl cladding in BWRs. In Proceedings of the ANS Winter Conference. Washington, DC, November 8–12, 2015. American Nuclear Society. \url https://www.osti.gov/biblio/1237610.[BibTeX]
  218. T. Harbison. Anisotropic grain boundary energy function for uranium dioxide. PhD thesis, Brigham Young University-Idaho, April 2015. \url https://tinyurl.com/ybkafssj.[BibTeX]
  219. R. Hu. A high-order system thermal-hydraulics model for advanced reactor safety analyses. In 16th International Topical Meting on Nuclear Reactor Thermal Hydraulics (NURETH-16). Chicago, Illinois, August 30–September 4, 2015. American Nuclear Society. \url https://tinyurl.com/yaromgma.[BibTeX]
  220. R. Hu and Y. Yu. Pseudo 3-D full-core conjugate heat transfer modeling of sodium fast reactors. In 16th International Topical Meting on Nuclear Reactor Thermal Hydraulics (NURETH-16). Chicago, Illinois, August 30–September 4, 2015. American Nuclear Society. \url https://tinyurl.com/y9s9usn4.[BibTeX]
  221. A. L. Alberti. Steady state modeling of the minimum critical core of the Transient Reactor Test Facility. Master's thesis, Oregon State University, October 2015. \url http://hdl.handle.net/1957/58315.[BibTeX]
  222. R. Hu, T. H. Fanning, T. Sumner, and Y. Yu. Status report on NEAMS System Analysis Module development. Technical Report ANL/NE-15/41, Argonne National Laboratory, December 2015. \url https://doi.org/10.2172/1233594.[BibTeX]
  223. R. Hu. An advanced one-dimensional finite element model for incompressible thermally expandable flow. Nuclear Technology, 190(3):313–322, 2015. \url https://doi.org/10.13182/NT14-78.[BibTeX]
  224. J. R. Harter. Predicting thermal conductivity in nuclear fuels using Rattlesnake-based deterministic phonon transport simulations. Master's thesis, Oregon State University, October 2015. \url http://hdl.handle.net/1957/58143.[BibTeX]
  225. C. Matthews. Fission Gas Bubble Behavior in Uranium Carbide. PhD thesis, Oregon State University, June 2015. \url http://tinyurl.com/q97rz6c.[BibTeX]
  226. N. M. George. Assessment of reactivity equivalence for enhanced accident tolerant fuels in light water reactors. PhD thesis, University of Tennessee, Knoxville, May 2015. \url http://tinyurl.com/y7jsgk5w.[BibTeX]
  227. A. Yankov. Analysis of reactor simulations using surrogate models. PhD thesis, University of Michigan, May 2015. \url http://tinyurl.com/h32ukat.[BibTeX]
  228. C. W. Arnold, J. Galloway, and C. Unal. Modeling lanthanide transport in metal fuels with BISON. In Proceedings of Global 2015. Paris, France, September 21–24, 2015. Société Française d'Energie Nucléaire (SFEN). \url http://tinyurl.com/hz4xvne.[BibTeX]
  229. A. J. McCaskey, S. Slattery, and J. J. Billings. Warthog: A MOOSE-based application for the direct code coupling of BISON and PROTEUS. Technical Report ORNL/TM–2015/532, Oak Ridge National Laboratory, September 2015. \url https://doi.org/10.2172/1255660.[BibTeX]
  230. D. Pizzocri, G. Pastore, T. Barani, E. Bruschi, L. Luzzi, and P. Van Uffelen. Modelling of burst release in oxide fuel and application to the TRANSURANUS code. In 11th International Conference on WWER Fuel Performance, Modelling and Experimental Support. Varna, Bulgaria, September 2015. IAEA and the Institute for Nuclear Research and Nuclear Energy (INRNE). \url http://tinyurl.com/zmpgu8c.[BibTeX]
  231. A. McCaskey, J. J. Billings, J. H. Deyton, and A. Wojtowicz. An update on NiCE Support for BISON. Technical Report ORNL/TM-2015/530, Oak Ridge National Laboratory, October 2015. \url https://doi.org/10.2172/1223084.[BibTeX]
  232. K. E. Barrett, K. D. Ellis, C. R. Glass, G. A. Roth, M. P. Teague, and J. Johns. Critical processes and parameters in the development of accident tolerant fuels drop-in capsule irradiation tests. Nuclear Engineering and Design, 294:38–51, December 2015. \url https://doi.org/10.1016/j.nucengdes.2015.07.074.[BibTeX]
  233. S. Simunovic and T. M. Besmann. Coupling of thermochemistry solver Thermochimica with MOOSE/BISON. Technical Report ORNL/TM-2015/56467, Oak Ridge National Laboratory, June 2015. \url https://doi.org/10.2172/1214026.[BibTeX]
  234. J. Mangeri, O. Heinonen, D. Karpeyev, and S. Nakhmanson. Influence of elastic and surface strains on the optical properties of semiconducting core-shell nanoparticles. Physical Review Applied, 4(1):014001 (10 pages), July 2015. \url https://doi.org/10.1103/PhysRevApplied.4.014001.[BibTeX]
  235. M. O. Delchini, J. C. Ragusa, and J. Morel. Entropy-based artificial viscosity stabilization for non-equilibrium Gray radiation-hydrodynamics. Journal of Computational Physics, 296:293–313, September 2015. \url https://doi.org/10.1016/j.jcp.2015.04.039.[BibTeX]
  236. D. Ruprecht, M. Winkel, and R. Krause. EWE—A coupled electro-mechanical heart model in the general purpose FEM framework MOOSE. In 86th Annual Meeting of the International Association of Applied Mathematics and Mechanics (GAMM 2015), 20. Lecce, Italy, March 23–27, 2015. \url http://tinyurl.com/ntbmtk3.[BibTeX]
  237. D. Ruprecht, M. Winkel, and R. Krause. EWE: Toward electro-mechanical heart simulations with MOOSE. Proceedings in Applied Mathematics and Mechanics, Special Issue: 86th Annual Meeting of the International Association of Applied Mathematics and Mechanics (GAMM), 15(1):683–684, October 2015. \url https://doi.org/10.1002/pamm.201510331.[BibTeX]
  238. X. Garnaud, X. Han, P. Jacquet, J.-M. Ndombo, and I. Limaiem. Multiscale analysis of heat transfer in coated fuel particle compacts – Application to the HTTR. Nuclear Engineering and Design, 282:106–115, February 2015. \url https://doi.org/10.1016/j.nucengdes.2014.11.031.[BibTeX]
  239. R. Hu. Verification and validation plan for the SFR system analysis module. Technical Report ANL/NE-14/14, Argonne National Laboratory, December 2014. \url https://doi.org/10.2172/1168234.[BibTeX]
  240. M. O. Delchini. Extension of the entropy viscosity method to the Multi-D Euler equations and the Seven-Equation Two-Phase model. PhD thesis, Texas A&M University, October 2014. \url https://oaktrust.library.tamu.edu/handle/1969.1/153891.[BibTeX]
  241. X. Wu, T. Kozlowski, and B. J. Heuser. Neutronics analysis of improved accident tolerant LWR fuel by modifying Zircaloy cladding of fuel pins. In Proceedings of the International Congress on Advances in Nuclear Power Plants (ICAPP), 14097 (8 pages). Charlotte, North Carolina, April 6–9, 2014. \url https://tinyurl.com/ya5yqpn9.[BibTeX]
  242. R. Hu and T. H. Fanning. Update on developments for the SFR System Analysis Module. Technical Report ANL/NE-14/9, Argonne National Laboratory, October 2014. \url https://doi.org/10.2172/1159321.[BibTeX]
  243. M. P. Short, D. Hussey, B. K. Kendrick, T. M. Besmann, C. R. Stanek, and S. Yip. Multiphysics modeling of porous CRUD deposits in nuclear reactors. Journal of Nuclear Materials, 443(1):579–587, November 2013. \url https://doi.org/10.1016/j.jnucmat.2013.08.014.[BibTeX]
  244. S. Simunovic, T. M. Besmann, and S. L. Voit. Benchmark problem for calculating oxygen potential in high burnup LWR fuel using the Thermochimica module in MOOSE/BISON. Technical Report ORNL/TM-2014/529, Oak Ridge National Laboratory, September 2014. \url https://doi.org/10.2172/1163165.[BibTeX]
  245. W. Liu, R. Montgomery, C. Stanek, and C. Tomé. Demonstration of atomistically-informed multiscale Zr alloy deformation models in Peregrine for normal and accident scenarios. Technical Report CASL-U-2014-201-000, LA-UR-14-27758, ANATECH Corporation, Pacific Northwest National Laboratory, Los Alamos National Laboratory, October 2014. \url http://tinyurl.com/orn7ldm.[BibTeX]
  246. S. Simunovic, S. L. Voit, and T. M. Besmann. Oxygen behavior and diffusion model in LWR fuel using the Thermochimica module in MOOSE/BISON. Technical Report ORNL/TM-2014/293, Oak Ridge National Laboratory, July 2014. \url http://tinyurl.com/ya8ysypm.[BibTeX]
  247. C. Unal and J. D. Galloway. Final report on accident tolerant fuel performance analysis of APMT-steel clad/UO$_2$ fuel and APMT-steel clad/UN-U$_3$Si$_5$ fuel concepts. Technical Report LA-UR-14-27175, Los Alamos National Laboratory, September 2014. \url http://tinyurl.com/yct6zdls.[BibTeX]
  248. A. M. Jokisaari and K. Thornton. Demonstration of Hyrax capabilities. Technical Report CASL-U-2013-0346-000, Consortium for Advanced Simulation of LWRs (CASL), March 2013. \url https://tinyurl.com/y8bcjjeg.[BibTeX]
  249. A. S. Butterfield. Exploration of the phase field framework MARMOT to include anisotropic grain boundaries with molecular dynamics. PhD thesis, Brigham Young University-Idaho, July 2013. \url https://doi.org/10.2172/1093887.[BibTeX]
  250. M. C. Teague. Characterization and modeling of high burn-up mixed oxide fuel. PhD thesis, Colorado School of Mines, May 2013. \url http://tinyurl.com/y9593vt9.[BibTeX]
  251. R. Montgomery, C. Stanek, W. Liu, and B. Kendrick. US DOE CASL Program fuel performance modeling for steady state and transient analysis of LWR fuel. In Proceedings of the IAEA technical meeting on modelling of water-cooled fuel including design-basis and severe accidents, 84–111. Chengdu, China, October 28–November 1, 2013. IAEA. IAEA-TECDOC-CD-1775, \url https://tinyurl.com/y7ttt69m.[BibTeX]
  252. E. Barker, D. Li, H. Zbib, and X. Sun. Gradient plasticity model and its implementation into MARMOT. Technical Report PNNL-22702, Pacific Northwest National Laboratory, August 2013. \url http://tinyurl.com/hb3ceo6.[BibTeX]
  253. Y. Li, S. Hu, and X. Sun. Report on the implementation of the homogeneous nucleation scheme in MARMOT-based phase field simulations. Technical Report PNNL-22829, Pacific Northwest National Laboratory, September 2013. \url http://tinyurl.com/pesukh3.[BibTeX]
  254. N. N. Carlson, C. Unal, and J. D. Galloway. Formulation of the constituent distribution model implemented into the BISON framework for the analysis of performance of metallic fuels with some initial simulations results. Technical Report LA-UR-13-26824, Los Alamos National Laboratory, August 2013. \url https://doi.org/10.2172/1091811.[BibTeX]
  255. T. L. Dickson, P. T. Williams, S. Yin, H. B. Klasky, S. K. Tadinada, and B. R. Bass. Grizzly/FAVOR interface project report. Technical Report ORNL/TM-2013/44094, Oak Ridge National Laboratory, June 2013. \url http://tinyurl.com/z38u6vn.[BibTeX]
  256. R. Hu, J. W. Thomas, and T. H. Fanning. Strategy for multi-scale single-phase flow coupling. Technical Report ANL/NE-13/4, Argonne National Laboratory, March 2013. \url http://tinyurl.com/hf5d3fj.[BibTeX]
  257. C. J. Stull, B. J. Williams, and C. Unal. Assessing the effect of parametric uncertainty on the FRAPCON-3.4 thermal conductivity model. Technical Report LA-UR-12-25426, Los Alamos National Laboratory, October 2012. \url http://tinyurl.com/y8lhek87.[BibTeX]
  258. T. Sumner, R. Hu, and T. H. Fanning. Verification test suite for systems analysis tools. Technical Report ANL/NE-12/61, Argonne National Laboratory, December 2012. \url http://tinyurl.com/yafthy7g.[BibTeX]
  259. J. D. Galloway, N. N. Carlson, and C. Unal. BISON framework for the analysis of performance of metallic fuels. Technical Report LA-UR-12-26297, Los Alamos National Laboratory, November 2012. \url https://doi.org/10.2172/1055254.[BibTeX]
  260. H. Sato, H. Park, and D. A. Knoll. Tightly coupled multiphysics simulations for prismatic reactors. In Proceedings of the 19th International Conference on Nuclear Engineering (ICONE19). Osaka, Japan, October 24–25, 2011. Paper no. ICONE19-43264, \url https://tinyurl.com/yd3zv4zc.[BibTeX]
  261. V. S. Mahadevan. High resolution numerical methods for coupled non-linear multi-physics simulations with applications in reactor analysis. PhD thesis, Texas A&M University, August 2010. \url http://tinyurl.com/psztmhu.[BibTeX]

INL Research using MOOSE

  1. Vincent M Laboure, Javier Ortensi, Yaqi Wang, Sebastian Schunert, Frederick N Gleicher, Mark D DeHart, and Richard C Martineau. Multiphysics steady-state simulation of the high temperature test reactor with mammoth, bison and relap-7. Technical Report, Idaho National Lab.(INL), Idaho Falls, ID (United States), 2019.[BibTeX]
  2. Stephanie A Pitts. Modeling and simulation of microstructure evolution and deformation in an irradiated environment. Technical Report, Idaho National Lab.(INL), Idaho Falls, ID (United States), 2019.[BibTeX]
  3. Pritam Chakraborty and Wen Jiang. Crystal plasticity-based creep model for solution-strengthened nickel-based alloys. International Journal of Materials and Structural Integrity, 13(1-3):144–159, 2019.[BibTeX]
  4. BW Spencer, WM Hoffman, and MA Backman. Modular system for probabilistic fracture mechanics analysis of embrittled reactor pressure vessels in the grizzly code. Nuclear Engineering and Design, 341:25–37, 2019.[BibTeX]
  5. Jacob Luke Bair, David G Abrecht, Dallas D Reilly, Matthew T Athon, and Jordan F Corbey. Phase field model of uranium carbide solidification through a combined kks and orientation field approach. Journal of Physics: Condensed Matter, 2019.[BibTeX]
  6. Vincent Labouré, Yaqi Wang, Javier Ortensi, Sebastian Schunert, Frederick Gleicher, Mark DeHart, and Richard Martineau. Hybrid super homogenization and discontinuity factor method for continuous finite element diffusion. Annals of Nuclear Energy, 128:443–454, 2019.[BibTeX]
  7. Larry K Aagesen, Daniel Schwen, Michael R Tonks, and Yongfeng Zhang. Phase-field modeling of fission gas bubble growth on grain boundaries and triple junctions in uo2 nuclear fuel. Computational Materials Science, 161:35–45, 2019.[BibTeX]
  8. Hans R Hammer, Jim E Morel, and Yaqi Wang. A weighted least-squares transport equation compatible with source iteration and voids. Nuclear Science and Engineering, 193(4):388–403, 2019.[BibTeX]
  9. Hailong Chen. A comparison study on peridynamic models using irregular non-uniform spatial discretization. Computer Methods in Applied Mechanics and Engineering, 345:539–554, 2019.[BibTeX]
  10. Jackson R Harter, Aria Hosseini, Todd Palmer, P Alex Greaney, and others. Prediction of thermal conductivity in dielectrics using fast, spectrally-resolved phonon transport simulations. arXiv preprint arXiv:1905.03898, 2019.[BibTeX]
  11. Olin W Calvin, Yaqi Wang, and Javier Ortensi. Implementation of depletion architecture in the mammoth reactor physics application. Technical Report, Idaho National Lab.(INL), Idaho Falls, ID (United States), 2019.[BibTeX]
  12. L Zou, JW Peterson, D Andrs, J Kelly, RN Slaybaugh, RC Martineau, HD Gougar, and AJ Novak. Pronghorn theory manual. Technical Report, Idaho National Lab.(INL), Idaho Falls, ID (United States), 2018.[BibTeX]
  13. S Schunert, F Gleicher, M DeHart, R Martineau, B Ganapol, and J Patel. A one-way coupled fast burst reactor benchmark through laplace transform. Technical Report, Idaho National Lab.(INL), Idaho Falls, ID (United States), 2018.[BibTeX]
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  243. R. Hu, J. W. Thomas, E. Munkhzul, T. H. Fanning, H. Zhang, and R. Martineau. Development of SFR primary system simulation capability for advanced system codes. Technical Report ANL/NE-13/11, Argonne National Laboratory, September 2013. \url http://www.ipd.anl.gov/anlpubs/2014/01/77535.pdf, \url https://doi.org/10.2172/1121040.[BibTeX]
  244. J. D. Hales, S. R. Novascone, G. Pastore, D. M. Perez, B. W. Spencer, and R. L. Williamson. BISON theory manual: The equations behind nuclear fuel analysis. Technical Report INL/EXT-13-29930, Idaho National Laboratory, October 2013. \url https://doi.org/10.2172/1107264.[BibTeX]
  245. S. R. Novascone, B. W. Spencer, R. L. Williamson, D. Andrs, J. D. Hales, and D. M. Perez. A comparison of thermomechanics coupling strategies in fuel pin and pressure vessel simulations. Technical Report INL/CON-12-27510, Idaho National Laboratory, August 2013. \url http://tinyurl.com/h7htocd, Transactions, SMiRT-22, San Francisco, CA, USA, August 18-23, 2013, Division III.[BibTeX]
  246. S. R. Novascone, B. W. Spencer, and J. D. Hales. Light water reactor sustainability program: Status report on the Grizzly code enhancements. Technical Report INL/EXT-13-30315, Idaho National Laboratory, September 2013. \url https://doi.org/10.2172/1115617.[BibTeX]
  247. D. M. Perez, R. L. Williamson, S. R. Novascone, G. Pastore, J. D. Hales, and B. W. Spencer. Assessment of BISON: A nuclear fuel performance analysis code. Technical Report INL/MIS-13-30314, Idaho National Laboratory, November 2013. \url http://tinyurl.com/zykc9ah.[BibTeX]
  248. M. R. Tonks, Y. Zhang, S. B. Biner, P. C. Millett, and X. Bai. Guidance to design grain boundary mobility experiments with molecular dynamics and phase-field modeling. Acta Materialia, 61(4):1373–1382, 2013. \url https://doi.org/10.1016/j.actamat.2012.11.014.[BibTeX]
  249. M. R. Tonks, S. B. Biner, P. C. Millett, and D. A. Andersson. Comparison between phase field simulations and experimental data from intragranular bubble growth in UO$_2$. Technical Report INL/CON-13-28301, Idaho National Laboratory, May 2013. \url http://tinyurl.com/j6l6j5b.[BibTeX]
  250. M. R. Tonks, P. C. Millett, P. Nerikar, S. Du, D. Andersson, C. R. Stanek, D. Gaston, D. Andrs, and R. Williamson. Multiscale development of a fission gas thermal conductivity model: Coupling atomic, meso and continuum level simulations. Journal of Nuclear Materials, 440(1–3):193–200, 2013. \url https://doi.org/10.1016/j.jnucmat.2013.05.008.[BibTeX]
  251. D. R. Gaston, J. W. Peterson, C. J. Permann, D. Andrs, A. E. Slaughter, and J. M. Miller. Continuous integration for concurrent computational framework and application development. In First Workshop on Sustainable Software for Science: Practice and Experiences (WSSSPE), In Conjunction with SC13. Denver, Colorado, November 2013. \url https://doi.org/10.6084/m9.figshare.790755.[BibTeX]
  252. J. D. Hales, R. L. Williamson, S. R. Novascone, D. M. Perez, B. W. Spencer, and G. Pastore. Multidimensional multiphysics simulation of TRISO particle fuel. Journal of Nuclear Materials, 443(1–3):531–543, November 2013. \url https://doi.org/10.1016/j.jnucmat.2013.07.070.[BibTeX]
  253. L. P. Swiler, G. Pastore, R. L. Williamson, and D. M. Perez. Sensitivity analysis of the fission gas behavior model in BISON. Technical Report SAND2013-3906, Sandia National Laboratories, May 2013. \url http://tinyurl.com/hr32mlr.[BibTeX]
  254. V. J. Rutledge. OSPREY Model. Technical Report INL/EXT-13-28150, Idaho National Laboratory, January 2013. \url https://doi.org/10.2172/1062195.[BibTeX]
  255. M. O. Delchini, J. C. Ragusa, and R. A. Berry. Entropy viscosity method applied to Euler equations. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  256. A. Alfonsi, C. Rabiti, D. Mandelli, J. J. Cogliati, and R. A. Kinoshita. RAVEN as a tool for dynamic probabilistic risk assessment: Software overview. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  257. C. Rabiti, D. Mandelli, A. Alfonsi, J. J. Cogliati, and R. A. Kinoshita. Mathematical framework for the analysis of dynamic stochastic systems with the RAVEN code. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  258. Y. Wang. Nonlinear diffusion acceleration for the multigroup transport equation discretized with $S_N$ and continuous FEM with Rattle$S_N$ake. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013. INL/CON-12-27929, \url http://tinyurl.com/zoalvmp.[BibTeX]
  259. M. Johnson and H. Zhao. Extended forward sensitivity analysis of one-dimensional isothermal flow. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013. INL/CON-12-27657, \url http://tinyurl.com/ztzh9m6.[BibTeX]
  260. F. N. Gleicher, B. W. Spencer, S. R. Novascone, R. L. Williamson, R. C. Martineau, M. Rose, T. J. Downar, and B. Collins. Coupling the core analysis program DeCART to the fuel performance application BISON. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  261. H. Zhang, L. Zou, D. Andrs, H. Zhao, and R. C. Martineau. Point kinetics calculations with fully coupled thermal fluids reactivity feedback. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  262. M. R. Tonks, S. B. Biner, P. C. Millett, and D. A. Andersson. Comparison between phase field simulations and experimental data from intragranular bubble growth in UO$_2$. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  263. L. Zou, J. W. Peterson, H. Zhao, H. Zhang, D. Andrs, and R. C. Martineau. Solving implicit multi-mesh flow and conjugate heat transfer problems with RELAP-7. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013. \url http://tinyurl.com/gp3cw8n.[BibTeX]
  264. S. R. Novascone, B. W. Spencer, D. Andrs, R. L. Williamson, J. D. Hales, and D. M. Perez. Results from tight and loose coupled multiphysics in nuclear fuels. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  265. D. M. Perez, R. L. Williamson, S. R. Novascone, T. K. Larson, J. D. Hales, B. W. Spencer, and G. Pastore. An evaluation of the nuclear fuel performance code BISON. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  266. J. D. Hales, D. R. Gaston, and D. Andrs. Algorithms for thermal and mechanical contact in nuclear fuel performance analysis. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  267. D. R. Gaston, C. J. Permann, D. Andrs, and J. W. Peterson. Massive hybrid parallelism for fully implicit multiphysics. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013.[BibTeX]
  268. L. P. Swiler, R. L. Williamson, and D. M. Perez. Calibration of a fuel relocation model in BISON. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2013). Sun Valley, Idaho, May 5–9, 2013. \url http://tinyurl.com/y98hqjwg.[BibTeX]
  269. P. C. Millett, M. R. Tonks, K. Chockalingam, Y. Zhang, and S. B. Biner. Three dimensional calculations of the effective Kapitza resistance of UO$_2$ grain boundaries containing intergranular bubbles. Journal of Nuclear Materials, 439(1–3):117–122, August 2013. \url https://doi.org/10.1016/j.jnucmat.2013.02.039.[BibTeX]
  270. K. Chockalingam, M. R. Tonks, J. D. Hales, D. R. Gaston, P. C. Millett, and L. Zhang. Crystal plasticity with Jacobian-Free Newton-Krylov. Computational Mechanics, 51(5):617–627, May 2013. \url https://doi.org/10.1007/s00466-012-0741-7.[BibTeX]
  271. L. Guo, H. Huang, D. R. Gaston, C. J. Permann, D. Andrs, G. D. Redden, C. Lu, D. T. Fox, and Y. Fujita. A parallel, fully coupled, fully implicit solution to reactive transport in porous media using the preconditioned Jacobian-Free Newton-Krylov method. Advances in Water Resources, 53:101–108, March 2013. \url https://doi.org/10.1016/j.advwatres.2012.10.010.[BibTeX]
  272. L. Zhang, M. R. Tonks, D. Gaston, J. W. Peterson, D. Andrs, P. C. Millett, and B. S. Biner. A quantitative comparison between $C^0$ and $C^1$ elements for solving the Cahn–Hilliard equation. Journal of Computational Physics, 236:74–80, March 2013. \url https://doi.org/10.1016/j.jcp.2012.12.001.[BibTeX]
  273. R. A. Berry, L. Zou, H. Zhao, D. Andrš, J. W. Peterson, H. Zhang, and R. C. Martineau. RELAP-7: Demonstrating seven-equation, two-phase flow simulation in a single-pipe, two-phase reactor core and steam separator/dryer. Technical Report INL/EXT-13-28750, Idaho National Laboratory, April 2013. \url https://doi.org/10.2172/1087687.[BibTeX]
  274. I. J. van Rooyen. Pre-irradiation testing and analysis to support the LWRS hybrid SiC-CMC-Zircaloy-04 unfueled rodlet irradiation. Technical Report INL/EXT-12-27189, Idaho National Laboratory, September 2012. \url https://doi.org/10.2172/1055814.[BibTeX]
  275. D. Andrš, R. Berry, D. R. Gaston, R. Martineau, J. W. Peterson, H. Zhang, H. Zhao, and L. Zou. RELAP-7 level 2 milestone report: Demonstration of a steady state single phase PWR simulation with RELAP-7. Technical Report INL/EXT-12-25924, Idaho National Laboratory, May 2012. \url https://doi.org/10.2172/1047196.[BibTeX]
  276. P. Medvedev. Fuel performance modeling results for representative FCRD irradtiation experiments: projected deformation in the annular AFC-3A U-10Zr fuel pins and comparison to alternative designs. Technical Report INL/EXT-12-27183, Idaho National Laboratory, September 2012.[BibTeX]
  277. M. P. Short. Effects of fluid flow on 2D and 3D coupled microscale simulations of porous boiling deposits (CRUD) in PWRs. In 9th International Topical Meeting on Nuclear Thermal-Hydraulics, Operation and Safety (NUTHOS-9). Kaohsiung, Taiwan, September 9–13, 2012.[BibTeX]
  278. S. R. Novascone, R. L. Williamson, J. D. Hales, M. R. Tonks, D. R. Gaston, C. J. Permann, D. Andrš, and R. C. Martineau. A multidimensional and multiphysics approach to nuclear fuel behavior simulation. In Proceedings of the Conference on Advances in Reactor Physics (PHYSOR). Knoxville, Tennessee, April 15–20, 2012. INL/CON-11-23761, \url https://www.osti.gov/biblio/22105710.[BibTeX]
  279. S. R. Novascone, J. D. Hales, B. W. Spencer, and R. L. Williamson. Assessment of PCMI simulation using the multidimensional multiphysics BISON fuel performance code. Technical Report INL/CON-12-24744, Idaho National Laboratory, September 2012. \url http://tinyurl.com/jedfbhu.[BibTeX]
  280. L. Guo, C. Lu, H. Huang, and D. R. Gaston. Reactive transport modeling using a parallel fully-coupled simulator based on preconditioned Jacobian-free Newton-Krylov. In Proceedings of the XIX International Conference on Water Resources (CMWR). Urbana, Illinois, June 17–22, 2012. INL/CON-12-25018, \url http://tinyurl.com/jqwaclv.[BibTeX]
  281. B. W. Spencer, J. D. Hales, S. R. Novascone, and R. L. Williamson. 3D simulation of missing pellet surface defects in light water reactor fuel rods. Technical Report INL/CON-12-24745, Idaho National Laboratory, September 2012. \url http://tinyurl.com/zrp9uhp.[BibTeX]
  282. F. N. Gleicher, Y. Wang, D. R. Gaston, and R. Martineau. The method of manufactured solutions for RattleSnake, a $S_N$ radiation transport solver inside the MOOSE framework. In Proceedings of the American Nuclear Society Annual Meeting. Chicago, Illinois, June 24–28, 2012. INL/CON-12-24712, \url https://www.osti.gov/biblio/1047190.[BibTeX]
  283. R. L. Williamson and S. R. Novascone. Application of the BISON fuel performance code to the FUMEX-III coordinated research project. Technical Report INL/EXT-12-25530, Idaho National Laboratory, April 2012. \url http://tinyurl.com/hrdrycm.[BibTeX]
  284. L. Zhang, M. R. Tonks, P. C. Millett, Y. Zhang, K. Chockalingam, and B. Biner. Phase-field modeling of temperature gradient driven pore migration coupling with thermal conduction. Computational Materials Science, 56:161–165, April 2012. \url https://doi.org/10.1016/j.commatsci.2012.01.002.[BibTeX]
  285. M. R. Tonks, D. R. Gaston, P. C. Millett, D. Andrs, and P. Talbot. An object-oriented finite element framework for multiphysics phase field simulations. Computational Materials Science, 51(1):20–29, January 2012. \url https://doi.org/10.1016/j.commatsci.2011.07.028.[BibTeX]
  286. D. K. Francis, J. Deang, R. S. Florea, D. R. Gaston, N. Lee, S. Nouranian, C. J. Permann, J. Rudd, D. Seely, W. R. Whittington, and M. F. Horstemeyer. Characterization and failure analysis of a polymeric clamp hanger component. Engineering Failure Analysis, 26:230–239, December 2012. \url https://doi.org/10.1016/j.engfailanal.2012.07.020.[BibTeX]
  287. A. A. Bingham, J. Ortensi, R. Jain, I. Grindeanu, and T. Tautges. SHARP/PRONGHORN interoperability: Mesh generation. Technical Report INL/EXT-12-27171, Idaho National Laboratory, September 2012. \url https://doi.org/10.2172/1060997.[BibTeX]
  288. Y. Wang, A. A. Bingham, J. Ortensi, and C. J. Permann. Improved neutronics treatment of burnable poisons for the prismatic HTR. In 6th International Topical Meeting on High Temperature Reactor Technology (HTR2012). Tokyo, Japan, October 28–November 1, 2012. \url http://tinyurl.com/j6z7m87.[BibTeX]
  289. C. Rabiti, A. Alfonsi, D. Mandelli, J. Cogliati, and R. Martineau. RAVEN as control logic and probabilistic risk assessment driver for RELAP-7. In Proceedings of the ANS Winter Meeting. San Diego, California, November 11–15, 2012. \url http://tinyurl.com/zvjupvt.[BibTeX]
  290. J. Ortensi, A. A. Bingham, D. Andrs, and R. C. Martineau. Initial coupling of the RELAP-7 and PRONGHORN applications. Technical Report INL/EXT-12-27350, Idaho National Laboratory, October 2012. \url https://doi.org/10.2172/1060984.[BibTeX]
  291. R. Podgorney, H. Huang, M. Plummer, and D. Gaston. A globally-implicit computational framework for physics-based simulation of coupled thermal-hydro-mechanical problems: Application to sustainability of geothermal reservoirs. Orkustofnun (National Energy Authority), June 2012. \url http://tinyurl.com/ybfuyroj.[BibTeX]
  292. J. D. Hales, S. R. Novascone, R. L. Williamson, D. R. Gaston, and M. R. Tonks. Solving nonlinear solid mechanics problems with the Jacobian-free Newton Krylov Method. Computer Modeling in Engineering & Sciences, 84(2):123–152, 2012. \url http://tinyurl.com/heohfr5.[BibTeX]
  293. D. Gaston, L. Guo, G. Hansen, H. Huang, R. Johnson, D. Knoll, C. Newman, H. K. Park, R. Podgorney, M. Tonks, and R. Williamson. Parallel algorithms and software for nuclear, energy, and environmental applications. Part II: Multiphysics software. Communications in Computational Physics, 12(3):834–865, September 2012. \url http://tinyurl.com/ybreodjj.[BibTeX]
  294. R. L. Williamson, J. D. Hales, S. R. Novascone, M. R. Tonks, D. R. Gaston, C. J. Permann, D. Andrs, and R. C. Martineau. Multidimensional multiphysics simulation of nuclear fuel behavior. Journal of Nuclear Materials, 423(1–3):149–163, 2012. \url https://doi.org/10.1016/j.jnucmat.2012.01.012.[BibTeX]
  295. R. Podgorney, C. Lu, and H. Huang. Thermo-hydro-mechanical modeling of working fluid injection and thermal energy extraction in EGS fractures and rock matrix. In Proceedings of Thirty-Seventh Workshop on Geothermal Reservoir Engineering. Stanford, California, January 30–February 1, 2012. \url http://tinyurl.com/gpkmsog.[BibTeX]
  296. A. E. Slaughter and N. Zabaras. A phase-tracking snow micro-structure model. In Proceedings of the 2012 International Snow Science Workshop, 395–397. Anchorange, Alaska, 2012. \url http://tinyurl.com/hjwhrhm.[BibTeX]
  297. D. P. Guillen, D. Gaston, and J. Tester. Multiphase flow modeling of biofuel production processes. Technical Report INL/CON-11-21680, Idaho National Laboratory, June 2011. \url http://tinyurl.com/gwrtgs3.[BibTeX]
  298. D. A. Knoll, H. Park, and C. Newman. Acceleration of $k$-eigenvalue/criticality calculations using the Jacobian-free Newton-Krylov method. Nuclear Science and Engineering, 167(2):133–140, 2011. \url https://doi.org/10.13182/NSE09-89.[BibTeX]
  299. D. Tomchak and others. Idaho National Laboratory Directed Research and Development FY-2009. Technical Report INL/EXT-09-17391, Idaho National Laboratory, March 2010. \url https://doi.org/10.2172/983355.[BibTeX]
  300. M. Tonks, D. Gaston, C. Permann, P. Millett, G. Hansen, and D. Wolf. A coupling methodology for mesoscale-informed nuclear fuel performance codes. Nuclear Engineering and Design, 240(10):2877–2883, 2010. \url https://doi.org/10.1016/j.nucengdes.2010.06.005.[BibTeX]
  301. R. Podgorney, H. Huang, and D. Gaston. Massively parallel fully coupled implicit modeling of coupled thermal-hydrological-mechanical processes for enhanced geothermal system reservoirs. In Proceedings of the 35th Workshop on Geothermal Reservoir Engineering. Stanford, California, February 2010. \url http://tinyurl.com/jv89o8k.[BibTeX]
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Cited by INL Researchers

  1. Michael Tonks, David Andersson, Ram Devanathan, Roland Dubourg, Anter El-Azab, Michel Freyss, Fernando Iglesias, Katalin Kulacsy, Giovanni Pastore, Simon R Phillpot, and others. Unit mechanisms of fission gas release: current understanding and future needs. Journal of Nuclear Materials, 504:300–317, 2018.[BibTeX]
  2. L. K. Aagesen and others. PRISMS: An integrated, open-source framework for accelerating predictive structural materials science. JOM, 70(10):2298–2314, October 2018. \url https://doi.org/10.1007/s11837-018-3079-6.[BibTeX]
  3. C. Blakely, H. Zhang, R. Szilard, A. Epiney, R. Vaghetto, and H. Ban. Demonstration of LOTUS multiphysics BEPU analysis framework for LB-LOCA simulations. Annals of Nuclear Energy, 122:8–22, December 2018. \url https://doi.org/10.1016/j.anucene.2018.08.027.[BibTeX]
  4. B. Wendt, L. Kerby, A. Tumulak, and J. Leppänen. Advancement of functional expansion capabilities: Implementation and optimization in Serpent 2. Nuclear Engineering and Design, 334:138–153, August 2018. \url https://doi.org/10.1016/j.nucengdes.2018.05.004.[BibTeX]
  5. M. R. Tonks, D. Andersson, R. Devanathan, R. Dubourg, A. El-Azab, M. Freyss, F. Iglesias, K. Kulacsy, G. Pastore, S. R. Phillpot, and M. Welland. Unit mechanisms of fission gas release: Current understanding and future needs. Journal of Nuclear Materials, 504:300–317, June 2018. \url https://doi.org/10.1016/j.jnucmat.2018.03.016.[BibTeX]
  6. I. Greenquist, M. R. Tonks, and Y. Zhang. Review of sintering and densification in nuclear fuels: Physical mechanisms, experimental results, and computational models. Journal of Nuclear Materials, 507:381–395, August 2018. \url https://doi.org/10.1016/j.jnucmat.2018.03.046.[BibTeX]
  7. C. Bolisetti, A. S. Whittaker, and J. L. Coleman. Linear and nonlinear soil-structure interaction analysis of buildings and safety-related nuclear structures. Soil Dynamics and Earthquake Engineering, 107:218–233, April 2018. \url https://doi.org/10.1016/j.soildyn.2018.01.026.[BibTeX]
  8. C. L. Pope, B. Savage, B. Johnson, C. Muchmore, L. Nichols, G. Roberts, E. Ryan, S. Suresh, A. Tahhan, R. Tuladhar, A. Wells, and C. Smith. Nuclear power plant mechanical component flooding fragility experiments status. Technical Report INL/EXT-17-42728, Idaho National Laboratory, July 2017. \url https://doi.org/10.2172/1376902.[BibTeX]
  9. A. Aitkaliyeva, L. He, H. Wen, B. Miller, X. M. Bai, and T. Allen. Irradiation effects in Generation IV nuclear reactor materials. In P. Yvon, editor, Structural Materials for Generation IV Nuclear Reactors, pages 253–283. 2017.[BibTeX]
  10. S. Shi, X. Zhang, X. Sun, and H. Zhang. Development of five-equation drift flux model for thermal non-equilibrium phenomena in LWRs. In Proceedings of the 25th International Conference on Nuclear Engineering (ICONE25), V006T08A118 (11 pages). Shanghai, China, July 2–6, 2017. Paper no. ICONE25-67981, \url https://doi.org/10.1115/ICONE25-67981.[BibTeX]
  11. C. Picoco, T. Aldemir, V. Rychkov, A. Alfonsi, D. Mandelli, and C. Rabiti. Coupling of RAVEN and MAAP5 for the dynamic event tree analysis of nuclear power plants. In Proceedings of the 27th European Safety and Reliability Conference (ESREL). Portorož, Slovenia, June 18–22, 2017. \url https://tinyurl.com/y752qsvx.[BibTeX]
  12. C. Matthews, C. Unal, J. Galloway, D. D. Keiser Jr., and S. L. Hayes. Fuel-cladding chemical interaction in U-Pu-Zr metallic fuels: A critical review. Nuclear Technology, 198(3):231–259, June 2017. \url https://doi.org/10.1080/00295450.2017.1323535.[BibTeX]
  13. A. Alfonsi, C. Rabiti, D. Mandelli, J. Cogliati, C. Wang, P. W. Talbot, D. P. Maljovec, and C. Smith. RAVEN theory manual and user guide. Technical Report INL/EXT-16-38178, Idaho National Laboratory, June 2016. \url https://doi.org/10.2172/1260312.[BibTeX]
  14. A. E. Slaughter, D. R. Gaston, C. J. Permann, J. W. Peterson, D. Andrš, J. M. Miller, B. K. Alger, and R. C. Martineau. Lessons from nuclear energy: Building snow and avalanche simulation tools using a common open-source framework. In International Snow Science Workshop (ISSW). Breckenridge, Colorado, October 3–7, 2016. INL/CON-16-38566, \url http://tinyurl.com/hmpvf27.[BibTeX]
  15. L. Zou, H. Zhao, and H. Zhang. Newton–Krylov method in application of solving two-phase problems using drift flux model. In Proceedings of the International Congress on Advances in Nuclear Power Plants (ICAPP), 430–439. San Francisco, California, April 17–20, 2016. \url https://tinyurl.com/y9j4zud6.[BibTeX]
  16. L. Zou, H. Zhao, and H. Zhang. Numerical implementation, verification and validation of two-phase flow four-equation drift flux model with Jacobian-free Newton-Krylov method. Annals of Nuclear Energy, 87(2):707–719, January 2016. \url https://doi.org/10.1016/j.anucene.2015.07.033.[BibTeX]
  17. Z. Hua, D. P. Guillen, W. Harris, and H. Ban. Three-dimensional FIB/EBSD characterization of irradiated HfAl$_3$-Al composite. In Proceedings of Top Fuel 2016. Boise, Idaho, September 11–16, 2016. INL/CON-16-37835, \url https://www.osti.gov/biblio/1358236.[BibTeX]
  18. R. H. Szilard, C. L. Smith, and R. C. Martineau. A demonstration of advanced safety analysis tools and methods applied to large break LOCA and fuel analysis for PWRs. In Proceedings of the Enlarged Halden Programme Group Meeting. Sandefjord, Norway, May 7–12, 2016. INL/CON-16-38068, \url https://www.osti.gov/biblio/1349204.[BibTeX]
  19. R. H. Szilard, J. L. Coleman, S. R. Prescott, C. Parisi, and C. L. Smith. RISMC toolkit and methodology research and development plan for external hazards analysis. Technical Report INL/EXT-16-38089, Idaho National Laboratory, March 2016. \url https://doi.org/10.2172/1406973.[BibTeX]
  20. R. L. Williamson, C. P. Folsom, G. Pastore, and S. Veeraraghavan. Reactivity Insertion Accident (RIA) capability status in the BISON fuel performance code. Technical Report INL/EXT-16-38861, Idaho National Laboratory, May 2016. \url https://doi.org/10.2172/1369377.[BibTeX]
  21. C. L. Smith, C. Rabiti, R. C. Martineau, and R. Szilard. Light Water Reactor Sustainability program: Risk-Informed Safety Margins Characterization (RISMC) pathway technical program plan. Technical Report INL/EXT-11-22977, Idaho National Laboratory, September 2016. \url https://doi.org/10.2172/1364769.[BibTeX]
  22. J. L. Coleman, C. L. Smith, and A. M. Kammerer. Plan to verify and validate multi-hazard risk-informed margin management methods and tools. Technical Report INL/EXT-16-39195, Idaho National Laboratory, July 2016. \url https://tinyurl.com/yaf3pbs7.[BibTeX]
  23. J. L. Coleman, C. Bolisetti, S. Veeraraghavan, C. Parisi, S. R. Prescott, and A. Gupta. Multi-hazard advanced seismic probabilistic risk assessment tools and applications. Technical Report INL/EXT-16-40055, Idaho National Laboratory, September 2016. \url https://doi.org/10.2172/1369534.[BibTeX]
  24. R. H. Szilard, J. Coleman, C. L. Smith, S. Prescott, A. Kammerer, R. Youngblood, and C. Pope. LWRS Program: Industry application external hazard analyses problem statement. Technical Report INL/EXT-15-36101, Idaho National Laboratory, July 2015. \url https://doi.org/10.2172/1369623.[BibTeX]
  25. C. L. Smith, D. Mandelli, and S. Prescott. Analysis of safety impacts from external flooding using the risk-informed safety margin characterization (RISMC) Toolkit. In Proceedings of the 23rd International Conference on Nuclear Engineering (ICONE23), ICONE23–1324 (6 pages). Chiba, Japan, May 17–21, 2015. \url https://inis.iaea.org/search/search.aspx?orig_q=RN:48047641.[BibTeX]
  26. C. L. Smith, S. Prescott, E. Ryan, D. Calhoun, R. Sampath, S. D. Anderson, and C. Casteneda. Flooding capability for river-based scenarios. Technical Report INL/EXT-15-37091, Idaho National Laboratory, October 2015. \url https://doi.org/10.2172/1245528.[BibTeX]
  27. C. L. Smith, S. Prescott, J. Coleman, E. Ryan, B. Bhandari, D. Sludern, C. Pope, and R. Sampath. Progress for the industry application external hazard analyses early demonstration. Technical Report INL/EXT-15-36749, Idaho National Laboratory, September 2015. \url https://doi.org/10.2172/1245520.[BibTeX]
  28. A. Alfonsi, C. Rabiti, D. Mandelli, J. Cogliati, and R. Kinoshita. Hybrid dynamic event tree sampling strategy in RAVEN code. In Proceedings of the International Topical Meeting on Probabilistic Safety Assessment and Analysis (PSA 2015), 1–9. Sun Valley, Idaho, April 26–30, 2015. \url https://tinyurl.com/yabc2ubn.[BibTeX]
  29. D. Mandelli and others. Modeling of a flooding induced station blackout for a pressurized water reactor using the RISMC toolkit. In Proceedings of the International Topical Meeting on Probabilistic Safety Assessment and Analysis (PSA 2015), 1–12. Sun Valley, Idaho, April 26–30, 2015. INL/CON-14-33735, \url https://www.osti.gov/biblio/1194026.[BibTeX]
  30. D. Mandelli and others. Reduced order model implementation in the Risk-Informed Safety Margin Characterization toolkit. Technical Report INL/EXT-15-36649, Idaho National Laboratory, September 2015. \url https://doi.org/10.2172/1260883.[BibTeX]
  31. R. Boring, D. Mandelli, J. Joe, C. Smith, and K. Groth. A research roadmap for computation-based human reliability analysis. Technical Report INL/EXT-15-36051, Idaho National Laboratory, August 2015. \url https://doi.org/10.2172/1230074.[BibTeX]
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  33. C. L. Smith, D. Mandelli, S. Prescott, A. Alfonsi, C. Rabiti, J. Cogliati, and R. Kinoshita. Light Water Reactor Sustainability Program: Analysis of pressurized water reactor station blackout caused by external flooding using the RISMC toolkit. Technical Report INL/EXT-14-32906, Idaho National Laboratory, August 2014. \url https://doi.org/10.2172/1168617.[BibTeX]
  34. H. Gougar. Enhanced severe transient analysis for prevention technical program plan. Technical Report INL/EXT-14-33228, Idaho National Laboratory, September 2014. \url https://doi.org/10.2172/1168658.[BibTeX]
  35. B. W. Spencer and H. Huang. Light Water Reactor Sustainability program: Survey of models for concrete degradation. Technical Report INL/EXT-14-32925, Idaho National Laboratory, August 2014. \url https://doi.org/10.2172/1168660.[BibTeX]
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Cited by non-INL Researchers

  1. Timothy Adowski and others. Statistical Inference of Heterogeneous Surface Catalycity Models Using Simulated Laser Absorption Spectroscopy in Reacting Flow. PhD thesis, State University of New York at Buffalo, 2019.[BibTeX]
  2. Rafał Gałek and Piotr Strzelczyk. Velocity profiles of an electrohydrodynamic flow generator: cfd and experiment. Journal of Electrostatics, 99:19–30, 2019.[BibTeX]
  3. Evan Coleman. Resilience for Asynchronous Iterative Methods for Sparse Linear Systems. PhD thesis, Old Dominion University, 2019.[BibTeX]
  4. Han Zhang, Jiong Guo, Jianan Lu, Jinlin Niu, Fu Li, and Yunlin Xu. The comparison between nonlinear and linear preconditioning jfnk method for transient neutronics/thermal-hydraulics coupling problem. Annals of Nuclear Energy, 132:357–368, 2019.[BibTeX]
  5. Carlo Fiorina. Gen-foam: an openfoam®-based multi-physics solver for nuclear reactor analysis. In OpenFOAM®, pages 211–221. Springer, 2019.[BibTeX]
  6. Alena Kopaničáková and Rolf Krause. Recursive multilevel trust region method with application to fully monolithic phase-field models of brittle fracture. arXiv preprint arXiv:1903.00379, 2019.[BibTeX]
  7. Ju Li, Yang Yang, and Michael P Short. More efficient and accurate simulations of primary radiation damage in materials with nanosized microstructural features or ion beams. Handbook of Materials Modeling: Applications: Current and Emerging Materials, pages 1–33, 2019.[BibTeX]
  8. Jiankai Yu, Hyunsuk Lee, Hanjoo Kim, Peng Zhang, and Deokjung Lee. Coupling of frapcon for fuel performance analysis in the monte carlo code mcs. Computer Physics Communications, 2019.[BibTeX]
  9. Shengyan Shang, Anil Kunwar, Yanfeng Wang, Lin Qu, Haitao Ma, and Yunpeng Wang. Growth behavior of preferentially scalloped intermetallic compounds at extremely thin peripheral sn/cu interface. Journal of Materials Science: Materials in Electronics, 30(3):2872–2887, 2019.[BibTeX]
  10. NU Aydemir, Alexandre Trottier, T Xu, M Echlin, and T Chin. Coupling of reactor transient simulations via the salome platform. Annals of Nuclear Energy, 126:434–442, 2019.[BibTeX]
  11. Saaketh Desai, Martin Hunt, and Alejandro Strachan. Online tools for uncertainty quantification in nanohub. JOM, pages 1–11, 2019.[BibTeX]
  12. Lars Bilke, Bernd Flemisch, Thomas Kalbacher, Olaf Kolditz, Rainer Helmig, and Thomas Nagel. Development of open-source porous media simulators: principles and experiences. Transport in Porous Media, pages 1–25, 2019.[BibTeX]
  13. Saad Alowayyed, Tomasz Piontek, James L Suter, Olivier Hoenen, Derek Groen, Onnie Luk, Bartosz Bosak, Piotr Kopta, Krzysztof Kurowski, Oliver Perks, and others. Patterns for high performance multiscale computing. Future Generation Computer Systems, 91:335–346, 2019.[BibTeX]
  14. Arthur T Motta, Laurent Capulongo, Long-Qing Chen, Mahmut Nedim Cinbiz, Mark Daymond, Donald A Koss, Evrard Lacroix, Giovanni Pastore, Pierre-Clement Simon, Michael Tonks, and others. Hydrogen in zirconium alloys: a review. Journal of Nuclear Materials, 2019.[BibTeX]
  15. Julian Andrej. Modeling and optimal control of multiphysics problems using the finite element method. PhD thesis, Christian-Albrechts Universität Kiel, 2019.[BibTeX]
  16. Rômulo M Silva, Benaia SJ Lima, José J Camata, Renato N Elias, and Alvaro LGA Coutinho. Communication–free parallel mesh multiplication for large scale simulations. In International Conference on Vector and Parallel Processing, 3–15. Springer, 2018.[BibTeX]
  17. Yu-Ting Hsu. Simulation of Local Electrochemistry in Solid Oxide Fuel Cell Microstructures by High Performance Computation. PhD thesis, Carnegie Mellon University, 2019.[BibTeX]
  18. Brody Bassett. Meshless Methods for the Neutron Transport Equation. PhD thesis, University of Michigan, 2018.[BibTeX]
  19. Derek Logtenberg, Chan Paul, and Emily Corcoran. BEHAVIOUR OF CANDU® FUEL AFTER A LOSS OF COOLANT ACCIDENT IN AN IRRADIATED FUEL BAY. PhD thesis, Royal Military College of Canada, 2019.[BibTeX]
  20. Diego Ferraro, Manuel Garcia, Uwe Imke, Ville Valtavirta, Jaakko Leppänen, and Victor Sanchez-Espinoza. Serpent/scf pin-level multiphysics solutions for the vera fuel assembly benchmark. Annals of Nuclear Energy, 128:102–114, 2019.[BibTeX]
  21. Hang Ke, Andres Garcia Jimenez, and Ioannis Mastorakos. A multiscale approach to predict the mechanical properties of copper nanofoams. MRS Advances, 4(5-6):293–298, 2019.[BibTeX]
  22. Jacob Gutiérrez-Kolar, Loïc Baggetto, Xiahan Sang, Dongwon Shin, Vitaliy Yurkiv, Farzad Mashayek, Gabriel M Veith, Reza Shahbazian-Yassar, and Raymond R Unocic. Interpreting electrochemical and chemical sodiation mechanisms and kinetics in tin antimony battery anodes using in situ tem and computational methods. ACS Applied Energy Materials, 2019.[BibTeX]
  23. Vitaliy Yurkiv, Tara Foroozan, Ajaykrishna Ramasubramanian, Reza Shahbazian-Yassar, and Farzad Mashayek. Phase-field modeling of solid electrolyte interface (sei) influence on li dendritic behavior. Electrochimica Acta, 265:609–619, 2018.[BibTeX]
  24. A. Miranville, W. Saoud, and R. Talhouk. On the Cahn–Hilliard/Allen–Cahn equations with singular potentials. Discrete and Continuous Dynamical Systems Series B, TBD(TBD):TBD, November 2018. \url https://doi.org/10.3934/dcdsb.2018308.[BibTeX]
  25. R. M. Silva, B. S. J. Lima, J. J. Camata, R. N. Elias, and A. L. G. A. Coutinho. Communication-free mesh multiplication for large scale simulations. In Proceedings of the 13th International Meeting on High Performance Computing for Computational Science (VECPAR 2018). São Pedro, Brazil, September 17–19, 2018. \url https://tinyurl.com/ycsxlyaj.[BibTeX]
  26. J. J. Cox, E. R. Homer, V. Tikare, and M. Kurata. Simulated microstructural and compositional evolution of U-Pu-Zr alloys using the Potts-Phase Field modeling technique. Metallurgical and Materials Transactions A, TBD(TBD):TBD, September 2018. \url https://doi.org/10.1007/s11661-018-4922-7.[BibTeX]
  27. O. van der Sluis, B. Vossen, J. Neggers, A. Ruybalid, K. Chockalingam, R. Peerlings, J. Hoefnagels, J. Remmers, V. Kouznetsova, P. Schreurs, and M. Geers. Advances in Delamination Modeling of Metal/Polymer Systems: Continuum Aspects, pages 83–128. Springer International Publishing, 2018, \url https://doi.org/10.1007/978-3-319-90362-0_3.[BibTeX]
  28. B. Sanderse and A. E. P. Veldman. Constraint-consistent Runge-Kutta methods for one-dimensional incompressible multiphase flow. ArXiv e-print, September 2018. \url https://arxiv.org/abs/1809.06114.[BibTeX]
  29. W. Setyawan, M. W. D. Cooper, K. J. Roche, R. J. Kurtz, B. P. Uberuaga, D. A. Andersson, and B. D. Wirth. Atomistic model of xenon gas bubble re-solution rate due to thermal spike in uranium oxide. Journal of Applied Physics, 124(7):075107 (11 pages), August 2018. \url https://doi.org/10.1063/1.5042770.[BibTeX]
  30. V. Yurkiv, A. L. Yarin, and F. Mashayek. Modeling of droplet impact onto polarized and non-polarized dielectric surfaces. Langmuir, July 2018. \url https://doi.org/10.1021/acs.langmuir.8b01443.[BibTeX]
  31. V. Yurkiv, T. Foroozan, A. Ramasubramanian, R. Shahbazian-Yassar, and F. Mashayek. The influence of stress field on Li electrodeposition in Li-metal battery. MRS Communications, July 2018. \url https://doi.org/10.1557/mrc.2018.146.[BibTeX]
  32. M.-O. G. Delchini, R. A. Lefebvre, W. D. Pointer, and B. T. Rearden. Integration of the Nek5000 computational fluid dynamics code to the NEAMS Workbench. In Transactions of the American Nuclear Society Annual Meeting (ANS 2018), volume 118, 966–969. Philadelphia, Pennsylvania, June 17–21, 2018. \url http://ansannual.org/wp-content/2018/Data/pdfs/418-25023.pdf.[BibTeX]
  33. R. A. Lefebvre, A. B. Thompson, B. R. Langley, and B. T. Rearden. NEAMS Workbench 1.0 Beta status. In Transactions of the American Nuclear Society Annual Meeting (ANS 2018), volume 118, 950–953. Philadelphia, Pennsylvania, June 17–21, 2018. \url http://ansannual.org/wp-content/2018/Data/pdfs/414-24571.pdf.[BibTeX]
  34. B. T. Rearden and R. A. Lefebvre. Objectives of the NEAMS Workbench. In Transactions of the American Nuclear Society Annual Meeting (ANS 2018), volume 118, 947–949. Philadelphia, Pennsylvania, June 17–21, 2018. \url http://ansannual.org/wp-content/2018/Data/pdfs/413-25034.pdf.[BibTeX]
  35. C. R. Stanek. Developments in fuel modeling within the NEAMS program. In Transactions of the American Nuclear Society Annual Meeting (ANS 2018), volume 118, 1323–1324. Philadelphia, Pennsylvania, June 17–21, 2018. \url http://ansannual.org/wp-content/2018/Data/pdfs/532-25338.pdf.[BibTeX]
  36. C. Zhang and G. Chen. Fast solution of neutron transport SP$_3$ equation by reduced basis finite element method. Annals of Nuclear Energy, 120:707–714, October 2018. \url https://doi.org/10.1016/j.anucene.2018.06.042.[BibTeX]
  37. J. T. Hwang and J. R. R. A. Martins. A computational architecture for coupling heterogeneous numerical models and computing coupled derivatives. ACM Transactions on Mathematical Software (TOMS), 44(4):37 (39 pages), June 2018. \url https://doi.org/10.1145/3182393.[BibTeX]
  38. M. F. Riyad, V. Chauhan, and M. Khafizov. Implementation of a multilayer model for measurement of thermal conductivity in ion beam irradiated samples using a modulated thermoreflectance approach. Journal of Nuclear Materials, 509:134–144, October 2018. \url https://doi.org/10.1016/j.jnucmat.2018.06.013.[BibTeX]
  39. F. Chao, D. Liu, J. Shan, and P. Wu. Development of temporal and spatial high-order schemes for two-fluid seven-equation two-pressure model and its applications in two-phase flow benchmark problems. International Journal for Numerical Methods in Fluids, 88(4):169–192, June 2018. \url https://doi.org/10.1002/fld.4515.[BibTeX]
  40. M. A. Prelas, N. E. White, D. A. Wisniewski, K. L. Walton, M. T. Tchouaso, M. A. Boraas, F. De La Torre Aguilar, H. Kasiwattanawut, T. B. Knewtson, J. R. Schutte, and M. L. Watermann. Thermal to optical energy conversion: A multi megawatt carbon dioxide laser driven by an extremely high temperature gas cooled reactor. Progress in Nuclear Energy, 107:155–171, August 2018. \url https://doi.org/10.1016/j.pnucene.2018.04.008.[BibTeX]
  41. Y. Miao, T. Yao, J. Lian, S. Zhu, S. Bhattacharya, A. Oaks, A. M. Yacout, and K. Mo. Nano-crystallization induced by high-energy heavy ion irradiation in UO$_2$. Scripta Materialia, 155:169–174, October 2018. \url https://doi.org/10.1016/j.scriptamat.2018.04.006.[BibTeX]
  42. B. T. Rearden, R. A. Lefebvre, B. R. Langley, A. B. Thompson, and J. P. Lefebvre. NEAMS Workbench 1.0 Beta. Technical Report ORNL/TM-2018/752, Oak Ridge National Laboratory, January 2018. \url https://doi.org/10.2172/1427614.[BibTeX]
  43. J. Chang, K. B. Nakshatrala, M. G. Knepley, and L. Johnsson. A performance spectrum for parallel computational frameworks that solve PDEs. Concurrency and Computation, 30(11):e4401 (25 pages), June 2018. \url https://doi.org/10.1002/cpe.4401, ArXiv e-print: \url https://arxiv.org/abs/1705.03625.[BibTeX]
  44. X. Zhou and F. Li. Jacobian-free Newton-Krylov nodal expansion methods with physics-based preconditioner and local elimination for three-dimensional and multigroup $k$-eigenvalue problems. Nuclear Science and Engineering, 190(3):238–257, June 2018. \url https://doi.org/10.1080/00295639.2018.1435136.[BibTeX]
  45. J. Yan, Z. Yang, A. Zhang, and Z. Mo. JSweep: A patch-centric data-driven approach for parallel sweeps on large-scale meshes. ArXiv e-print, March 2018. \url https://arxiv.org/abs/1803.09876.[BibTeX]
  46. Y. Cao, Z. Mo, L. Xiao, H. Wang, Z. Ai, and Z. Zhang. Efficient visualization of high-resolution virtual nuclear reactor. Journal of Visualization, 21(5):857–871, October 2018. \url https://doi.org/10.1007/s12650-018-0487-1.[BibTeX]
  47. I. Dumnernchanvanit. Characterization and mitigation of CRUD at pressurized water reactor conditions. PhD thesis, Massachusetts Institute of Technology, June 2017. \url http://hdl.handle.net/1721.1/115003.[BibTeX]
  48. M. Aufiero and M. Fratoni. A new approach to the stabilization and convergence acceleration in coupled Monte Carlo-CFD calculations: The Newton method via Monte Carlo perturbation theory. Nuclear Engineering and Technology, 49(6):1181–1188, September 2017. \url https://doi.org/10.1016/j.net.2017.08.005.[BibTeX]
  49. S. DeWitt and K. Thornton. Phase field modeling of microstructural evolution. In D. Shin and J. Saal, editors, Computational Materials System Design, chapter 4, pages 67–87. Springer, 2017.[BibTeX]
  50. J. Chang, M. S. Fabien, M. G. Knepley, and R. T. Mills. Comparative study of finite element methods using the Time-Accuracy-Size (TAS) spectrum analysis. ArXiv e-print, February 2018. \url https://arxiv.org/abs/1802.07832.[BibTeX]
  51. D. Z. Huang, P.-O. Persson, and M. J. Zahr. High-order, linearly stable, partitioned solvers for general multiphysics problems based on implicit-explicit Runge-Kutta schemes. ArXiv e-print, March 2018. \url https://arxiv.org/abs/1803.11372.[BibTeX]
  52. V. Vasconcelos, A. Santos, D. Campolina, G. Theler, and C. Pereira. Coupled unstructured fine-mesh neutronics and thermal-hydraulics methodology using open software: A proof-of-concept. Annals of Nuclear Energy, 115:173–185, May 2018. \url https://doi.org/10.1016/j.anucene.2018.01.021.[BibTeX]
  53. Y. Liu, M. Nishimura, M. Seydaliev, and M. Piro. Backbone: A multiphysics framework for coupling nuclear codes based on CORBA and MPI. ASME Journal of Nuclear Engineering and Radiation Science, 3(1):011020 (10 pages), January 2017. Paper No. NERS-16-1002, \url https://doi.org/10.1115/1.4034061.[BibTeX]
  54. B. T. Rearden, R. A. Lefebvre, A. B. Thompson, and B. R. Langley. Introduction to the Nuclear Energy Advanced Modeling and Simulation Workbench. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2017). Jeju Island, Korea, April 16–20, 2017. \url https://www.osti.gov/servlets/purl/1376414.[BibTeX]
  55. H. Zhang, J. Xiao, and T. Jordan. Large eddy simulation of turbulent flows using the CFD code GASFLOW-MPI. In Proceedings of the International Conference on Mathematics and Computational Methods Applied to Nuclear Science & Engineering (M&C 2017). Jeju Island, Korea, April 16–20, 2017. \url https://tinyurl.com/y8qg2wc3.[BibTeX]
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  57. M. Diehl. Review and outlook: mechanical, thermodynamic, and kinetic continuum modeling of metallic materials at the grain scale. MRS Communications, 7(4):735–746, December 2017. \url https://doi.org/10.1557/mrc.2017.98.[BibTeX]
  58. C. Fiorina, M. Hursin, and A. Pautz. Extension of the GeN-Foam neutronic solver to SP3 analysis and application to the CROCUS experimental reactor. Annals of Nuclear Energy, 101:419–428, March 2017. \url https://doi.org/10.1016/j.anucene.2016.11.042.[BibTeX]
  59. K. Jareteg. Development of fine-mesh methodologies for coupled calculations in Light Water Reactors. PhD thesis, Chalmers University of Technology, June 2017. \url https://tinyurl.com/ybzyskxl.[BibTeX]
  60. M. H. A. Piro, A. Prudil, M. J. Welland, W. Richmond, A. Bergeron, E. Torres, C. Maxwell, J. Pencer, N. Harrison, and M. Floyd. Nuclear fuel modelling and perspectives on Canadian efforts in fuel development. In D. Singh and others, editors, Proceedings of the 12th Pacific Rim Conference on Ceramic and Glass Technology, 253–264. Waikoloa, Hawaii, May 21–26, 2017. \url https://tinyurl.com/y85a9sof.[BibTeX]
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