Group meetings
The next meeting is scheduled on Nov. 26, 2024 at 8 a.m. (CST). A zoom invitation will be sent via the RaDIATE Collaboration email list one week prior to the meeting.
Working documents
An Excel file collecting the material data useful for the RaDIATE collaboration is under development and can be shared upon request. Please contact Frederique Pellemoine at fpellemo@fnal.gov for more information.
Publication list related to Titanium and Titanium Alloys
| Release date | Title | Authors | Reference | Keywords |
|---|---|---|---|---|
| 2024 | Microstructural Evolution of Ion Irradiated Commercially Pure Titanium | A. Amroussia, C.J. Boehlert, F. Pellemoine, D. Grummon, W. Mittig, T.R. Bieler, M. Li, W.Y. Chen | JNM Volume 599, October 2024, 155105 | titanium irradiation, ionization, microstructure, dislocations |
| 2023 | Insights into radiation resistance of titanium alloys from displacement cascade simulations | Ankit Roy, David J. Senor, Danny J. Edwards, Andrew M. Casella, Ram Devanathan | JNM Volume 586, 1 December 2023, 154695 | Ti-15V-3Cr-3Sn-3Al, Ti-6Al-4V, α and β-phases, Molecular dynamics, PKA cascade simulations, Vacancy and interstitial clustering, Displacement threshold energies |
| 2020 | Low-temperature proton irradiation damage of isotropic nuclear grade IG-430 graphite | N.Simos, P.Hurh, N.Mokhov, M.Snead, M.Topsakal, M.Palmer, S.Ghose, H.Zhong, Z.Kotsina, D.J.Sprouster | JNM Volume 542, 15 December 2020, 152438 | irradiation damage, post-irradiation annealing, very high-temperature reactor, graphite IG-430 |
| 2020 | Tensile behavior of dual-phase titanium alloys under high-intensity proton beam exposure: radiation-induced omega phase transformation in Ti-6Al-4V | T. Ishida, E. Wakai, S. Makimura, A. M. Casella, D. J. Edwards, R. Prabhakaran, D. J. Senor, K. Ammigan, S. Bidhar, P. G. Hurh, F. Pellemoine, C. J. Densham, M. D. Fitton, J. M. Bennett, D. Kim, N. Simos, M. Hagiwara, N. Kawamura, S. Meigo, K. Yonehara, On behalf of the RaDIATE COLLABORATION | JNM Volume 541, December 2020, 152413 | titanium alloy, omega phase, radiation damage, accelerator target, beam window |
| 2020 | Why Does Titanium Alloy Beam Window Become Brittle After Proton Beam Exposure ? ~ Research and Development on the Accelerator Target and Beam Window Materials | RaDIATE International Collaboration, J-PARC Center, High Energy Accelerator Research Organization (KEK), Japan Atomic Energy Agency (JAEA), Fermi National Accelerator Laboratory (FNAL), Pacific Northwest National Laboratory (PNNL), Brookhaven National Laboratory (BNL), Science and Technology Facilities Council (STFC), Rutherford Appleton Laboratory (RAL) | KEK Press Release | titanium alloy, omega phase, radiation damage, accelerator target, beam window |
| 2020 | Why Does Titanium Alloy Beam Window Become Brittle After Proton Beam Exposure? | RaDIATE International Collaboration, J-PARC Center, High Energy Accelerator Research Organization (KEK), Japan Atomic Energy Agency (JAEA), Fermi National Accelerator Laboratory (FNAL), Pacific Northwest National Laboratory (PNNL), Brookhaven National Laboratory (BNL), Science and Technology Facilities Council (STFC), Rutherford Appleton Laboratory (RAL) | J-PARC Press Release | titanium alloy, omega phase, radiation damage, accelerator target, beam window |
| 2020 | Estimation of reliable displacements-per-atom based on athermal-recombination-corrected model in radiation environments at nuclear fission, fusion, and accelerator facilities | Y. Iwamoto, S. Meigo, S. Hashimoto | JNM Volume 538, September 2020, 152261 | arc-dpa, NRT-dpa, primary radiation damage, nuclear interaction product, high energy |
| 2020 | Measurement of displacement cross-sections of copper and iron for proton with kinetic energies in the range 0.4 – 3 GeV | H. Matsuda, S. Meigo, Y. Iwamoto, M. Yoshida, S. Hasegawa, F. Maekawa, H. Iwamoto, T. Nakamoto, S. Makimura | Journal of Nuclear Science and Technology, Volume 57, issue 10 (2020) 1141-1151 | accelerator, accelerator-driven system, proton, radiation damage, radiation dose, iron, PHITS, target |
| 2020 | Measurement of Displacement Cross Section of Structural Materials Utilized in the Proton Accelerator Facilities with the Kinematic Energy above 400 MeV | S. Meigo, H. Matsuda, Y. Iwamoto, M. Yoshida, S. Hasegawa, F. Maekawa, H. Iwamoto, T. Nakamoto, T. Ishida, and S. Makimura | JPS Conf. Proc. 28, 061004 (2020) | displacement cross section, DPA, proton irradiation, copper |
| 2020 | Failure investigation of nuclear grade POCO graphite target in high-energy neutrino physics through numerical simulation | S. Bidhar, N. Simos, D. Senor, P. Hurh | Nuclear Materials and Energy 24 (2020) 100761 | neutrino physics, isotropic graphite, radiation damage, annealing, X-ray diffraction, finite element analysis, empirical formula, thermal stress wave |
| 2020 | Radiation Damage Studies on Titanium Alloys as High-Intensity Proton Accelerator Beam Window Materials | T. Ishida, E. Wakai, S. Makimura, P. Hurh, K. Ammigan, A. M. Casella, D. J. Edwards, D. J. Senor, C. J. Densham, M. D. Fitton, J. M. Bennett, D. Kim, N. Simos, M. Calviani, and C. Torregrosa Martin, On behalf of the RaDIATE COLLABORATION | JPS Conf. Proc. 28, 041001 (2020) | titanium alloy, beam window, proton beam, radiation damage |
| 2018 | Study of the radiation damage effect on Titanium metastable beta alloy by high intensity proton beam | T. Ishida, E. Wakai, M. Hagiwara, S. Makimura, M. Tada,D. M. Asner, A. Casella, A. Devaraj, D. Edwards, R. Prabhakaran, D. Senor, M. Hartz, S. Bhadra, A. Fiorentini, M. Cadabeschi, J. Martin, A. Konaka, A. Marino, A. Atherthon, C.J. Densham, M. Fitton, K. Ammigan, P. Hurh | Nuclear Materials and Energy, Volume 15, May 2018, Pages 169-174 | titanium alloy, proton beam, radiation damage, target, beam window |
| 2015 | Swift heavy ion irradiation damage in Ti-6Al-4V and Ti-6Al-4V-1B: Study of the microstructure and mechanical properties | A. Amroussia, M. Avilov, C. J. Boehlert, F. Durantel, C. Grygiel, W. Mittig, I. Monnet, F. Pellemoine | NIMB Volume 365, December 2015, Pages 515-521 | swift heavy ion (SHI) irradiation damage, microstructure, mechanical properties, titanium alloys |