This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
International Atomic Energy Agency. (2013). Training guidelines in non-destructive testing techniques. Vienna: IAEA.International Atomic Energy Agency. (2013). . Vienna: IAEA.Search in Google Scholar
Chang, C. Y., Che, W. H., Saw, L. H., & Arpia, A. A. (2021). Performance analysis of a printedcircuit heat exchanger with a novel mirror-symmetric channel design. Energies, 14(14), 4252. https://doi.org/10.3390/en14144252.ChangC. Y.CheW. H.SawL. H.ArpiaA. A. (2021). Performance analysis of a printedcircuit heat exchanger with a novel mirror-symmetric channel design. , 14(14), 4252. https://doi.org/10.3390/en14144252.Search in Google Scholar
Aakre, S. (2018). Nuclear code case development of printed-circuit heat exchangers with thermal and mechanical performance testing. In 6th International Supercritical CO2 Power Cycles Symposium, Pittsburgh.AakreS. (2018). . In 6th International Supercritical CO2 Power Cycles Symposium, Pittsburgh.Search in Google Scholar
Liskien, H., & Paulsen, A. (1973). Neutron production cross sections and energies for the reactions T(p,n)3He, D(d,n)3He, and T(d,n)4He. Atom. Data Nucl. Data Tabl., 11(7), 569–619. DOI: 10.1016/S0092-640X(73)80081-6.LiskienH.PaulsenA. (1973). Neutron production cross sections and energies for the reactions T(p,n)3He, D(d,n)3He, and T(d,n)4He. ., 11(7), 569–619. DOI: 10.1016/S0092-640X(73)80081-6.Open DOISearch in Google Scholar
Advacam. (2023, November). MiniPIX TPX2. Retrieved November 13, 2023, from https://advacam. com/camera/minipix-tpx2/.Advacam. (2023, November). . Retrieved November 13, 2023, from https://advacam. com/camera/minipix-tpx2/.Search in Google Scholar
Llopart, X., Ballabriga, R., Campbell, M., Tlustos, L., & Wong, W. (2007). Timepix, a 65k programmable pixel readout chip for arrival time, energy and/or photon counting measurements. Nucl. Instrum. Methods Phys. Res. Sect. A-Accel. Spectrom. Dect. Assoc. Equ., 581 (1/2), 485–494.LlopartX.BallabrigaR.CampbellM.TlustosL.WongW. (2007). Timepix, a 65k programmable pixel readout chip for arrival time, energy and/or photon counting measurements. ., 581 (1/2), 485–494.Search in Google Scholar
Poikela, T., Plosila, J., Westerlund, T., & Campbell, M. (2014). Timepix3: a 65K channel hybrid pixel readout chip with simultaneous ToA/ToT and sparse readout. JINST, 9(5), C05013.PoikelaT.PlosilaJ.WesterlundT.CampbellM. (2014). Timepix3: a 65K channel hybrid pixel readout chip with simultaneous ToA/ToT and sparse readout. , 9(5), C05013.Search in Google Scholar
Wong, W. S., Alozy, J., Ballabriga, R., Campbell, M., Kremastiotis, I., Llopart, X., Poikela, T., Sriskaran, V., Tlustos, L., & Turecek, D. (2020) Introducing Timepix2, a frame-based pixel detector readout ASIC measuring energy deposition and arrival time. Radiat. Meas., 131, 106230.WongW. S.AlozyJ.BallabrigaR.CampbellM.KremastiotisI.LlopartX.PoikelaT.SriskaranV.TlustosL.TurecekD. (2020) Introducing Timepix2, a frame-based pixel detector readout ASIC measuring energy deposition and arrival time. ., 131, 106230.Search in Google Scholar
Bergmann, B., Burian, P., Manek, P., & Pospisiul, S. (2019). 3D reconstruction of particle tracks in a 2 mm thick CdTe hybrid pixel detector. Eur. Phys. J. C, 79, 165. https://doi.org/10.1140/epjc/s10052-019-6673-z.BergmannB.BurianP.ManekP.PospisiulS. (2019). 3D reconstruction of particle tracks in a 2 mm thick CdTe hybrid pixel detector. , 79, 165. https://doi.org/10.1140/epjc/s10052-019-6673-z.Search in Google Scholar
Zatko, B., Sagatova, A., Gal, N., Novak, A., Osvald, J., Bohacek, P., Polansky, S., Jakubek, J., & Kovacova, E. (2022) From a single silicon carbide detector to pixelated structure for radiation imaging camera. JINST, 17, C12005.ZatkoB.SagatovaA.GalN.NovakA.OsvaldJ.BohacekP.PolanskyS.JakubekJ.KovacovaE. (2022) From a single silicon carbide detector to pixelated structure for radiation imaging camera. , 17, C12005.Search in Google Scholar
Sagatova, A., Zatko, B., & Necas, V. (2018). From single GaAs detector to sensor for radiation imaging camera. Appl. Surf. Sci., 461(2), 3–9.SagatovaA.ZatkoB.NecasV. (2018). From single GaAs detector to sensor for radiation imaging camera. ., 461(2), 3–9.Search in Google Scholar
Zaťko, B., Zaprazny, Z., Jakubek, J., Sagatova, A., Bohacek, P., Sekacova, M., Korytar, D., Necas, V., Zemlicka, J., Mora, Y., & Pichotka, M. (2018) Imaging performance of Timepix detector based on semi-insulating GaAs. JINST, 13, C01034.ZaťkoB.ZapraznyZ.JakubekJ.SagatovaA.BohacekP.SekacovaM.KorytarD.NecasV.ZemlickaJ.MoraY.PichotkaM. (2018) Imaging performance of Timepix detector based on semi-insulating GaAs. , 13, C01034.Search in Google Scholar
Novak, A., Granja, C., Sagatova, A., Zach, V., Stursa, J., & Oancea, C. (2023) Spectral tracking of proton beams by the Timepix3 detector with GaAs, CdTe and Si sensors. JINST, 18, C01022.NovakA.GranjaC.SagatovaA.ZachV.StursaJ.OanceaC. (2023) Spectral tracking of proton beams by the Timepix3 detector with GaAs, CdTe and Si sensors. , 18, C01022.Search in Google Scholar
Jakubek, J., & Uher, J. (2009) Fast neutron detector based on TimePix pixel device with micrometer spatial resolution. In Proceedings of the 2009 IEEE Nuclear Science Symposium Conference Record (NSS/MIC), 24 October–1 November 2009, Orlando, FL, U.S.A. (pp. 1113–1116). DOI: 10.1109/NSS-MIC.2009.5402420.JakubekJ.UherJ. (2009) Fast neutron detector based on TimePix pixel device with micrometer spatial resolution. In , Orlando, FL, U.S.A. (pp. 1113–1116). DOI: 10.1109/NSS-MIC.2009.5402420.Open DOISearch in Google Scholar
Bergmann, B., Nelson, R. O., O’Donnell, J. M., Pospisil, S., Solc, J., & Vykydal, Z. (2014). Time-of-flight measurement of fast neutrons with Timepix detectors. JINST, 9, C05048.BergmannB.NelsonR. O.O’DonnellJ. M.PospisilS.SolcJ.VykydalZ. (2014). Time-of-flight measurement of fast neutrons with Timepix detectors. , 9, C05048.Search in Google Scholar
Granja, C., Uhlar, R., Chuprakov, I., Alexa, P., Sansarbayar, E., Gledenov, Y. M., Poklop, D., Olsansky, V., Marek, L., Vuolo, M., & Pacik, J. (2023). Detection of fast neutrons with the pixel detector Timepix3. JINST, 18, P01003.GranjaC.UhlarR.ChuprakovI.AlexaP.SansarbayarE.GledenovY. M.PoklopD.OlsanskyV.MarekL.VuoloM.PacikJ. (2023). Detection of fast neutrons with the pixel detector Timepix3. , 18, P01003.Search in Google Scholar
Granja, C., Jakubek, J., Polansky, S., Zach, V., Krist, P., Chvatil, D., Stursa, J., Sommer, M., Plac, O., Kodaira, S., & Martisikova, M. (2018). Resolving power of pixel detector Timepix for wide-range electron, proton and ion detection. Nucl. Instrum. Methods Phys. Res. Sect. A-Accel. Spectrom. Dect. Assoc. Equ., 908, 60–71.GranjaC.JakubekJ.PolanskyS.ZachV.KristP.ChvatilD.StursaJ.SommerM.PlacO.KodairaS.MartisikovaM. (2018). Resolving power of pixel detector Timepix for wide-range electron, proton and ion detection. ., 908, 60–71.Search in Google Scholar
Sedlackova, K., Sagatova, A., Zatko, B., Necas, V., Solar, M., & Granja, C. (2016) MCNPX simulation of the silicon carbide semiconductor detector response to fast neutrons from D-T nuclear reaction. Int. J. Modern Phys.-Conf. Ser., 44, 1660226.SedlackovaK.SagatovaA.ZatkoB.NecasV.SolarM.GranjaC. (2016) MCNPX simulation of the silicon carbide semiconductor detector response to fast neutrons from D-T nuclear reaction. ., 44, 1660226.Search in Google Scholar
Simakov, S., Majerle, M., & Kostal, M. (2023) Recoil and charged particle energy spectra from the natSi(n,x) reaction and the Si semiconductor detector response to the 14 MeV neutrons. Radiat. Phys. Chem., 203, 110624.SimakovS.MajerleM.KostalM. (2023) Recoil and charged particle energy spectra from the natSi(n,x) reaction and the Si semiconductor detector response to the 14 MeV neutrons. ., 203, 110624.Search in Google Scholar
Jakubek, J., Granja, C., Hartmann, B., Jaekel, O., Martisikova, M., Opalka, L., & Pospisil, S. (2011). Selective detection of secondary particles and neutrons produced in ion beam therapy with 3D sensitive voxel detector. JINST, 6, C12010.JakubekJ.GranjaC.HartmannB.JaekelO.MartisikovaM.OpalkaL.PospisilS. (2011). Selective detection of secondary particles and neutrons produced in ion beam therapy with 3D sensitive voxel detector. , 6, C12010.Search in Google Scholar
Ziegler, J. F., Biersack, J. P., & Ziegler, M. D. (2008). SRIM – The stopping and range of ions in matter. NC, USA: Lulu Press Co.ZieglerJ. F.BiersackJ. P.ZieglerM. D. (2008). . NC, USA: Lulu Press Co.Search in Google Scholar
Marek, L., Granja, C., Jakubek, J., Ingerle, J., Turecek, D., Vuolo, M., & Oancea, C. (2023). Data Processing Engine (DPE): Data Analysis Tool for Particle Tracking and Mixed Radiation Field Characterization with Pixel Detectors Timepix. JINST, prepared for publishing. https://arxiv.org/pdf/2310.15723v1.pdf.MarekL.GranjaC.JakubekJ.IngerleJ.TurecekD.VuoloM.OanceaC. (2023). Data Processing Engine (DPE): Data Analysis Tool for Particle Tracking and Mixed Radiation Field Characterization with Pixel Detectors Timepix. , prepared for publishing. https://arxiv.org/pdf/2310.15723v1.pdf.Search in Google Scholar
Python Software Foundation. (2023 November). python™. [computer software]. Retrieved November 13, 2023, from https://www.python.org/.Python Software Foundation. (2023November). . [computer software]. Retrieved November 13, 2023, from https://www.python.org/.Search in Google Scholar
Chadwick, M. B., Herman, M., Oblozinsky, P., Dunn, M. E., Danon, Y., Kahler, A. C., Smith, D. L., Pritychenko, B., Arbanas, G., Arcilla, R., Brewer, R., Brown, D. A., Capote, R., Carlson, A. D., Cho, Y. S., Derrien, H., Guber, K., Hale, G. M., Hoblit, S., Hollaway, S., Johnson, T. D., Kawano, T., Kiedrowski, B. C., Kim, H., Kunieda, S., Larson, N. M., Leal, L., Lestone, J. P., Little, R. C., McCutchan, E. A., MacFarlane, R. E., MacInnes, M., Mattoon, C. M., McKnight, R. D., Mughabghab, S. F., Nobre, G. P. A., Palmiotti, G., Palumbo, A., Pigni, M. T., Pronyaev, V. G., Sayer, R. O., Sonzogni, A. A., Summers, N. C., Talou, P., Thompson, I. J., Trkov, A., Vogt, R. L., van der Marck, S. C., Wallner, A., White, M. C., Wiarda, D., & Young, P. G. (2011). ENDF/B-VII.1 nuclear data for science and technology: Cross sections, covariances, fission product yields and decay data. Nuclear Data Sheets, 112(12), 2887–2996. https://www.sciencedirect.com/science/article/pii/S009037521100113X.ChadwickM. B.HermanM.OblozinskyP.DunnM. E.DanonY.KahlerA. C.SmithD. L.PritychenkoB.ArbanasG.ArcillaR.BrewerR.BrownD. A.CapoteR.CarlsonA. D.ChoY. S.DerrienH.GuberK.HaleG. M.HoblitS.HollawayS.JohnsonT. D.KawanoT.KiedrowskiB. C.KimH.KuniedaS.LarsonN. M.LealL.LestoneJ. P.LittleR. C.McCutchanE. A.MacFarlaneR. E.MacInnesM.MattoonC. M.McKnightR. D.MughabghabS. F.NobreG. P. A.PalmiottiG.PalumboA.PigniM. T.PronyaevV. G.SayerR. O.SonzogniA. A.SummersN. C.TalouP.ThompsonI. J.TrkovA.VogtR. L.van der MarckS. C.WallnerA.WhiteM. C.WiardaD.YoungP. G. (2011). ENDF/B-VII.1 nuclear data for science and technology: Cross sections, covariances, fission product yields and decay data. , 112(12), 2887–2996. https://www.sciencedirect.com/science/article/pii/S009037521100113X.Search in Google Scholar