|
| 1 | +% MOOSE |
| 2 | +% "The constitutive equations in Section 2.4 were implemented as a material model in ... MOOSE..." |
| 3 | +@Article{Karan_2026, |
| 4 | + author = {Baibhav Karan and Santosh Kumar Shaw and Apu Sarkar and Kiomars Moheimani and Sabyasachi Chatterjee and Mingxing Zhang and Ayan Bhowmik}, |
| 5 | + title = {{Orientation and strain-rate effects on high-temperature plasticity of 316L stainless steel fabricated by laser powder bed fusion}}, |
| 6 | + journal = {Additive Manufacturing}, |
| 7 | + month = mar, |
| 8 | + year = 2026, |
| 9 | + volume = 119, |
| 10 | + pages = {105115 (17 pages)}, |
| 11 | + note = {\url{https://doi.org/10.1016/j.addma.2026.105115}} |
| 12 | +} |
| 13 | + |
| 14 | +% MOOSE |
| 15 | +% "This CPPFFM has been implemented with the finite element method using ... (MOOSE) ..." |
| 16 | +@Article{WHu_2026, |
| 17 | + author = {Wenxuan Hu and Junyang Peng and Shaopu Su and Xianmin Chen and Min Yi and Wanlin Guo}, |
| 18 | + title = {Crystal-plastic phase-field modeling of short crack behavior in laser shock peened material}, |
| 19 | + journal = {European Journal of Mechanics - A/Solids}, |
| 20 | + month = jul # {--} # aug, |
| 21 | + year = 2026, |
| 22 | + volume = 118, |
| 23 | + pages = {106075 (xx pages)}, |
| 24 | + note = {\url{https://doi.org/10.1016/j.euromechsol.2026.106075}} |
| 25 | +} |
| 26 | + |
| 27 | +% MOOSE |
| 28 | +% "The model is numerically implemented using ... (MOOSE)..." |
| 29 | +@Article{ZhenhuiZhang_2024, |
| 30 | + author = {Zhenhui Zhang and Renjia Zhang and Shen Sun and Min Yi}, |
| 31 | + title = {A thermo-mechanically coupled phase-field fatigue fracture model}, |
| 32 | + journal = {Acta Mechanica}, |
| 33 | + month = feb, |
| 34 | + year = 2026, |
| 35 | + volume = 237, |
| 36 | + number = 2, |
| 37 | + pages = {709--726}, |
| 38 | + note = {\url{https://doi.org/10.1007/s00707-024-04163-y}} |
| 39 | +} |
| 40 | + |
| 41 | +% MOOSE |
| 42 | +% "All simulations were performed using FALCON ... within the MOOSE ... framework..." |
| 43 | +% https://pangea.stanford.edu/ERE/db/GeoConf/papers/SGW/2026/Kumawat.pdf |
| 44 | +% Note: these Geothermal Reservoir conference papers all had the same page number when I first found them. |
| 45 | +@InProceedings{Kumawat_2026, |
| 46 | + author = {Piyush Kumar Kumawat and Lynn Brendon Munday and Robert Podgorney and Milind Deo and John McLenann}, |
| 47 | + title = {{Tradeoffs between planar and geologic discrete fracture networks for EGS: Insights from Utah FORGE}}, |
| 48 | + booktitle = {{Proceedings of the 51st Workshop on Geothermal Reservoir Engineering}}, |
| 49 | + address = {Stanford, California}, |
| 50 | + pages = {SGP-TR-230 (8 pages)}, |
| 51 | + month = feb # {~9--11,}, |
| 52 | + year = 2026, |
| 53 | + note = {\url{https://tinyurl.com/4z9mywn}} |
| 54 | +} |
| 55 | + |
| 56 | +% MOOSE |
| 57 | +% "The numerical simulations in this study were performed using ... (MOOSE) ..." |
| 58 | +% https://pangea.stanford.edu/ERE/db/GeoConf/papers/SGW/2026/Fakeye.pdf |
| 59 | +% Note: these Geothermal Reservoir conference papers all had the same page number when I first found them. |
| 60 | +@InProceedings{Fakeye_2026, |
| 61 | + author = {Victor Fakeye and Travis McLing and Christine Doughty and Yingqi Zhang and Patrick Dobson and Trevor Atkinson}, |
| 62 | + title = {Stochastic thermo-hydro modeling and neural network surrogate development for thermal resource assessment of the galleries-to-calories geobattery}, |
| 63 | + booktitle = {{Proceedings of the 51st Workshop on Geothermal Reservoir Engineering}}, |
| 64 | + address = {Stanford, California}, |
| 65 | + pages = {SGP-TR-230 (14 pages)}, |
| 66 | + month = feb # {~9--11,}, |
| 67 | + year = 2026, |
| 68 | + note = {\url{https://tinyurl.com/2y6ktdna}} |
| 69 | +} |
| 70 | + |
| 71 | +% MOOSE |
| 72 | +% "The constitutive models are incorporated into MOOSE..." |
| 73 | +@Article{CYuan_2026, |
| 74 | + author = {Chongxi Yuan and Alejandro Ria{\~{n}}o and Marisol Koslowski}, |
| 75 | + title = {Dynamic hot spot induced damage in energetic materials using a hot-spot surrogate model}, |
| 76 | + journal = {Journal of Applied Physics}, |
| 77 | + month = feb, |
| 78 | + year = 2026, |
| 79 | + volume = 139, |
| 80 | + number = 6, |
| 81 | + pages = {065101 (14 pages)}, |
| 82 | + note = {\url{https://doi.org/10.1063/5.0291680}} |
| 83 | +} |
| 84 | + |
| 85 | +% MOOSE/RACCOON |
| 86 | +% "... results were obtained via implementation in RACCOON ... built upon the MOOSE framework ..." |
| 87 | +@Misc{Zeng_2026, |
| 88 | + author = {Bo Zeng and John E. Dolbow}, |
| 89 | + title = {A complete phase-field fracture model for brittle materials subjected to thermal shocks}, |
| 90 | + month = feb, |
| 91 | + year = 2026, |
| 92 | + howpublished = {ArXiv e-print}, |
| 93 | + note = {\url{https://arxiv.org/abs/2602.09031}} |
| 94 | +} |
| 95 | + |
1 | 96 | % MOOSE |
2 | 97 | % "Flow is ... implemented in the PorousFlow module ... of ... (MOOSE) ..." |
3 | 98 | @Article{Rau_2026, |
@@ -42,6 +137,7 @@ @Article{WXChen_2026 |
42 | 137 | } |
43 | 138 |
|
44 | 139 | % MOOSE |
| 140 | +% "This section presents the second crystal plasticity model ..., which was ... implemented within ... MOOSE ..." |
45 | 141 | % Personal communication with Matti Lindroos: "we used ... MOOSE with strain grad enhanced CP based on Nicolo Grilli's app with small modifications" |
46 | 142 | @Article{ABiswas_2026, |
47 | 143 | author = {Abhishek Biswas and Matti Lindroos and Nicol{\`{o}} Grilli and Michael Salvini and Sicong Ren and Paul Chekhonin and Guilherme Corr{\'{e}}a Soares and Andris Freimanis and Mahmoud Mostafavi}, |
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