Papers that used Py-SPHViewer:

When users cite the code in their papers, I can keep track of the citation and know what is the real impact of Py-SPHViewer in the community. If your research project or paper used the code and is not listed here, please let me know so that we can add it to the list. Some of the papers that used Py-SPHViewer are listed below:

• Chaikin et al. (2022), The importance of the way in which supernova energy is distributed around young stellar populations in simulations of galaxies, arXiv: 2203.07134 (Link)

• Marioni et al. (2022), Numerical simulations of bar formation in the Local Group, arXiv: 2201.05162 (Link)

• Cavanagh et al. (2022), The evolution of barred galaxies in the EAGLE simulations, arXiv: 2112.12935 (Link)

• Rasera et al. (2021), The RayGalGroupSims cosmological simulation suite for the study of relativistic effects: an application to lensing-matter clustering statistics, arXiv: 2111.08745 (Link)

• de Graaff et al. (2021), Observed structural parameters of EAGLE galaxies: reconciling the mass-size relation in simulations with local observations, arXiv: 2110.02235 (Link)

• Gargiulo et al. (2021), High and low Sérsic index bulges in Milky Way- and M31-like galaxies: origin and connection to the bar with TNG50, arXiv: 2111.13712 (Link)

• Manuwal et al. (2021), Drivers of asymmetry in synthetic HI emission line profiles of galaxies in the EAGLE simulation, arXiv: 2109.11214 (Link)

• Chaikin et al. (2021), Simulations of 60Fe entrained in ejecta from a near-Earth supernova: Effects of observer motion, arXiv: 2109.11242 (Link)

• Benavides et al. (2021), Quiescent Ultra-diffuse galaxies in the field originating from backsplash orbits, arXiv: 2109.01677 (Link)

• Sawala et al. (2021), The SIBELIUS Project: E Pluribus Unum, arXiv: 2103.12073 (Link)

• Robertson (2021), The galaxy-galaxy strong lensing cross-sections of simulated ΛCDM galaxy clusters, arXiv: 2101.12067 (Link)

• Bondarenko et al. (2021), Account of baryonic feedback effect in the γ-ray measurements of intergalactic magnetic fields, arXiv: 2106.02690 (Link)

• Davies et al. (2021), Quenching and morphological evolution due to circumgalactic gas expulsion in a simulated galaxy with a controlled assembly history, arXiv: 2006.13221 (Link)

• Hill et al. (2021), The morphology of star-forming gas and its alignment with galaxies and dark matter haloes in the EAGLE simulations, arXiv: 2102.13603 (Link)

• Haggar et al. (2021), The Three Hundred Project: Substructure in hydrodynamical and dark matter simulations of galaxy groups around clusters, arXiv: 2101.03178 (Link)

• Rost et al. (2020), The ThreeHundred: the structure and properties of cosmic filaments in the outskirts of galaxy clusters, arXiv: 2012:02850 (Link)

• Arámburo-García et al. (2020), Magnetization of the intergalactic medium in the IllustrisTNG simulations: the importance of extended, outflow-driven bubbles, arXiv: 2011.11581 (Link)

• Meneghetti et al. (2020), An excess of small-scale gravitational lenses observed in galaxy clusters, Science, 369, 6509 (Link)

• Hernández-Aguayo et al. (2020), Galaxy formation in the brane world I: overview and first results, arXiv: 2006.15467 (Link)

• Vance et al. (2020), Titanium and Iron in the Cassiopeia A Supernova Remnant, arXiv: 2005.03777 (Link)

• Power et al. (2020), NIFTY galaxy cluster simulations - VI. The dynamical imprint of substructure on gaseous cluster outskirts, arXiv: 1810.00534 (Link)

• Wang et al. (2020), Universal structure of dark matter haloes over a mass range of 20 orders of magnitude, Nature 585, 39 (Link)

• Brown et al. (2020), Connecting the structure of dark matter haloes to the primordial power spectrum: arXiv:2005.12933 (Link)

• Lovell et al. (2020), First Light And Reionisation Epoch Simulations (FLARES) I: Environmental Dependence of High-Redshift Galaxy Evolution: arXiv:2004.07283 (Link)

• Aramburo Garcia et al. (2020), Effective photon mass and (dark) photon conversion in the inhomogeneous Universe: arXiv:2003.10465 (Link)

• Parul et al. (2020), Orbital ingredients for cooking X-structures in edge-on galaxies: arXiv:2002.06627 (Link)

• Borrow et al. (2019), Cosmological baryon transfer in the SIMBA simulations: arXiv:1910.00594 (Link)

• Trayford et al. (2019), Fade to grey: systematic variation of the galaxy attenuation curves with galaxy properties in EAGLE, arXiv:1908.08956 (Link)

• Benitez-Llambay et al. (2019), Baryon-induced dark matter cores in the EAGLE simulations, arXiv:1810.04186 (Link)

• Pearson et al. (2019), Identifying Galaxy Mergers in Observations and Simulations with Deep Learning, arXiv:1902.10626 (Link)

• Mackenszie et al. (2019), Linking gas and galaxies at high redshift: MUSE surveys the environments of six damped Lyman alpha galaxies at z~3, arXiv:1904.07254 (Link)

• vas Son et al. (2019), Galaxies with monstrous black holes in galaxy cluster environments, arXiv:1901.03156 (Link)

• Trayford & Schaye (2018), Resolved galaxy scaling relations in the EAGLE simulation: star formation, metallicity and stellar mass on kpc scales, arXiv:1812.06984 (Link)

• Genina et al. (2018), The distinct stellar metallicity populations of simulated Local Group dwarfs, arXiv:1812.04839 (Link)

• Bose et al. (2018), ETHOS - an Effective Theory of Structure Formation: detecting dark matter interactions through the Lyman-alpha forest, arXiv:1811.10630 (Link)

• Benitez-Llambay et al. (2018), Baryon-induced dark matter cores in the EAGLE simulations, arXiv:1810.04186 (Link)

• Cui et al. (2018), The Three Hundred project: a large catalogue of theoretically modelled galaxy clusters for cosmological and astrophysical applications, MNRAS 480, 2898. (Link)

• Barber et al. (2018), Calibrated, cosmological hydrodynamical simulations with variable IMFs III: Spatially-resolved properties and evolution, arXiv:1807.11310 (Link)

• Salcido et al. (2017), The impact of dark energy on galaxy formation. What does the future of our Universe hold? , arXiv:1710.06861 (Link)

• Benitez-Llambay et al. (2017), The vertical structure of gaseous galaxy discs in cold dark matter halos, arXiv:1707.08046 (Link)

• Leo et al. (2017), The Effect of Thermal Velocities on Structure Formation in N-body Simulations of Warm Dark Matter, arXiv:1706.07837 (Link)

• Ludlow & Angulo (2016), Einasto Profiles and The Dark Matter Power Spectrum, arXiv:1610.04620 (Link)

• Benitez-Llambay et al. (2016), The properties of “dark” LCDM halos in the Local Group, arXiv:1609.01301 (Link)

• Algorry et al. (2016), Barred galaxies in the EAGLE cosmological hydrodynamical simulation, arXiv:1609.05909 (Link)

• Ferrero et al. (2016), Size matters: abundance matching, galaxy sizes, and the Tully-Fisher relation in EAGLE, arXiv:1607.03100 (Link)

• Benitez-Llambay et al. (2016), Mergers and the outside-in formation of dwarf spheroidals, arXiv:1511.06188 (Link)

• Benitez-Llambay et al. (2015), The imprint of reionization on the star formation histories of dwarf galaxies, arXiv:1405.5540 (Link)

• Algorry et al. (2014), Counterrotating stars in simulated galaxy discs, arXiv:1311.1215 (Link)

• Benitez-Llambay et al. (2013), Dwarf Galaxies and the Cosmic Web, arXiv:1211.0536 (Link)