[{"content":"","externalUrl":null,"permalink":"/authors/","section":"Authors","summary":"","title":"Authors","type":"authors"},{"content":" The Clumpy 2-Phase Obscuring Torus Model # C2PO-Torus is a physically-based X-ray spectral model for AGN, designed to be a direct counterpart to the SKIRTOR infrared AGN torus model. It was generated using the SKIRT radiative transfer code and is intended for use with XSPEC.\nThe model is presented in Gilbert et al. (2026, In prep), where it is applied to the X-ray spectral analysis of 43 AGN from the 12-Micron Galaxy Sample.\nA rotating view of the clumpy two-phase torus geometry. Model Description # C2PO-Torus is based on a two-phase clumpy wedge-shaped torus geometry, in which dust is distributed between high-density clumps and low-density interclump regions. The model uses an anisotropic primary emission source at the centre (Netzer 1987), with the torus shape defined by inner/outer radii and a half-opening angle.\nDensity maps of the xy plane (left) and xz plane (right) slices, showing the distribution of clumps within the torus. Higher density clumps are shown in yellow, while lower density interclump regions are plotted in purple. The key feature of C2PO-Torus is that its parameters map directly onto those of the SKIRTOR IR model, enabling:\nX-ray spectral fitting results to be used as priors for SED fitting Stronger constraints on torus properties by exploiting synergies between X-ray and IR regimes Better disentangling of AGN and star-formation emission components Model Components # The model consists of two additive XSPEC table model components that must be linked during fitting:\nComponent Description C2POTorusD Directly absorbed intrinsic power law emission C2POTorusR Reprocessed emission (scattered and reflected emission, emission lines) Free Parameters # Parameter Symbol Range Units Half-opening angle \\(\\Theta\\) 10 \u0026ndash; 80 degrees Inclination \\(i\\) 0 \u0026ndash; 90 degrees Equatorial column density \\(N_{\\mathrm{H,eq}}\\) \\(10^{21}\\) \u0026ndash; \\(5 \\times 10^{25}\\) \\(\\mathrm{cm}^{-2}\\) Photon index \\(\\Gamma\\) 1.4 \u0026ndash; 2.6 Radial dust gradient \\(p\\) 0, 1 Reprocessed scaling \\(A_R\\) free The inclination convention is \\(i = 0°\\) for face-on (Seyfert 1) and \\(i = 90°\\) for edge-on (Seyfert 2). The equatorial column density represents the average value of the smooth model before clump generation. The average line-of-sight column density can be estimated as:\n\\[N_{\\mathrm{H,los}} = N_{\\mathrm{H,eq}} \\times e^{-|\\cos i|}\\] Fixed Geometry Parameters # Parameter Value \\(R_{\\mathrm{in}}\\) 0.5 pc \\(R_{\\mathrm{out}}\\) 15 pc \\(R_{\\mathrm{ratio}}\\) 30 \\(R_{\\mathrm{clump}}\\) 0.4 pc Filling factor 0.25 \\(f_{\\mathrm{clumps}}\\) 0.97 \\(q\\) (polar dust gradient) 1 Usage in XSPEC # Basic Model Setup # const * phabs * (A_R * C2POTorusR + C2POTorusD) Where phabs models Galactic absorption and all parameters of C2POTorusD and C2POTorusR should be linked. The scaling constant \\(A_R\\) can be fixed at 1 or left free.\nAdditional components (e.g. mekal for soft excess) can be added as needed, as shown in this example fit to NGC 7469:\nconst * phabs * (mekal + A_R * C2POTorusR + C2POTorusD) The model fitted to the spectrum of NGC 7469, showing the mekal component (dot-dash), C2POTorusD (dotted), C2POTorusR (dashed), and total model (solid). Blue and red show the XMM-Newton and NuSTAR models respectively. Computing Intrinsic Luminosity # To calculate the intrinsic \\(2-10\\) keV luminosity:\nFreeze all parameters at their final fitted values Delete all model components except C2POTorusD Set \\(N_{\\mathrm{H,eq}} = 0.1\\) (lowest value, negligible obscuration) Use the lum command Uncertainties on the intrinsic luminosity are found using the relative uncertainties of the normalisation.\nTips # For sources with strong relativistic reflection, consider adding relxill alongside C2PO-Torus, linking physical parameters where possible The model performs best for Compton-thin to moderately Compton-thick sources For very Compton-thick sources (\\(N_H \u003e 10^{25}\\ \\mathrm{cm}^{-2}\\)), the model may overestimate the intrinsic luminosity \u0026ndash; a future update will improve coverage at high column densities Download # The model files for use in XSPEC will be made available here upon publication of the paper.\nReference # If you use C2PO-Torus in your work, please cite:\nA New Hope for AGN SED Fitting: X-Ray Spectral Analysis of 12MGS AGN with the C2PO-Torus Model C.J.E. Gilbert et al. (2026) MNRAS, in prep.\nContact # For questions about the model or to request early access to the model files, please contact Carys Gilbert.\n","externalUrl":null,"permalink":"/c2po-torus/","section":"C2PO-Torus","summary":"","title":"C2PO-Torus","type":"c2po-torus"},{"content":"","externalUrl":null,"permalink":"/categories/","section":"Categories","summary":"","title":"Categories","type":"categories"},{"content":"I am a Master\u0026rsquo;s student in Astrophysics at the University of Cape Town, specialising in X-Ray Astronomy and Active Galactic Nuclei (AGN).\nMy current research focuses on the multiwavelength analysis of local AGN from the 12-Micron Galaxy Sample (12MGS). I work with data from X-ray observatories such as Chandra, XMM-Newton and NuSTAR, as well as radio data from MeerKAT, to characterise the properties of AGN and their host galaxies.\nOutside of Astronomy you can generally find me hanging out with my two cats, Frodo and Turnip!\n","externalUrl":null,"permalink":"/","section":"Home","summary":"","title":"Home","type":"page"},{"content":" First-Author # A New Hope for AGN SED Fitting: X-Ray Spectral Analysis of 12MGS AGN with the C2PO-Torus Model C.J.E. Gilbert et al. In prep, undergoing internal review. Expected submission to MNRAS in early 2026.\nThis paper presents the X-ray spectral analysis of 43 AGN from the 12-Micron Galaxy Sample of IR-bright galaxies, along with a new physically-based X-ray spectral model, C2PO-Torus, designed to assist with SED fitting.\nCo-Authored # Beyond the Dot: an LRD-like nucleus at the Heart of an IR-Bright Galaxy and its implications for high-redshift LRDs P. Rinaldi, G.H. Rieke, Z. Wu, C.J.E. Gilbert et al. Submitted to ApJ, in review. arXiv:2507.17738\nFilling the Gap in Cluster Evolution: JWST\u0026rsquo;s Glimpse into a Young, Star-Forming Cluster at Cosmic Noon P. Rinaldi, S. Alberts, C.N.A. Willmer, C. Carreira, C.C. Williams, G. Noirot, C.J.E. Gilbert et al. Submitted to ApJ, in review. arXiv:2602.2416v1\n","externalUrl":null,"permalink":"/publications/","section":"Publications","summary":"","title":"Publications","type":"publications"},{"content":"","externalUrl":null,"permalink":"/series/","section":"Series","summary":"","title":"Series","type":"series"},{"content":"","externalUrl":null,"permalink":"/tags/","section":"Tags","summary":"","title":"Tags","type":"tags"}]