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Last modified: 7 November 2019

URL: http://cxc.harvard.edu/caldb/downloads/Release_notes/CALDB_v4.8.5.html

CalDB 4.8.5 Public Release Notes

Public Release Date: 07 Nov 2019


I. INTRODUCTION

CalDB 4.8.5 is an upgrade to the Chandra CalDB, which includes the following items:

For the CIAO 4.11 / CalDB 4.8.5 release notes see How CalDB 4.8.5 Affects Your Analysis.

II. SUMMARY OF CHANGES

A. ACIS CONTAM Version N0013

Location: $CALDB/data/chandra/acis/contam/
Filename: acisD1999-08-13contamN0013.fits

Analysis of recent observations of previously-observed cosmic sources, such as certain clusters of galaxies and supernova remnants, have resulted in unexpected increased temperatures and reduced flux levels that have been traced to a deviation of the ACIS contaminant model (CONTAM in CalDB) from calibration measurements. As illustrated in Fig. 1 below, the solid trace which represents the current (version N0012) contamination model in CalDB is no longer representative of the most recent data points from Abell 1795 or Mkn 421 ("big dither") observations. It seems that the contaminant deposition with time has not leveled off, as suggested in previous measurements, but has resumed its inexorable quasi-linear climb. Hence it is time to update this model to improve its performance since about 2018 for center-array optical depths and for center-to-edge spatial modeling since about 2015. Indeed, the new model specifies a linear layer depth with time since 2016, as well as a linear center-to-edge dependence with time since around 2010-2011.

supporting/Tau_660eV_center_N12.gif
Fig. 1: The current contamination model (version N0012), normalized for comparison with optical depth Tau derived at 0.66 keV from Abell 1795 and Mkn 421 "big dither" LETG/ACIS-S observations. While the model is anticipating the contaminant deposition leveling off with time beyone 2016, the actual contamination appears to be increasing linearly with time since 2015.

The current and new models are compared with calibration data in the technical details section below.

See the why page for more general information on the ACIS OBF contaminant.

CIAO SCRIPTS/TOOLS AFFECTED:

See the script fluximage, which uses mkinstmap

See the script specextract, which uses mkwarf

See the script fullgarf, which uses mkgarf

THREADS AFFECTED:

For exposure-corrected imaging analysis with ACIS, see the threads:

For imaging spectroscopy with ACIS, see the threads:

For grating spectroscopy with ACIS, see the threads:

III. TECHNICAL DETAILS

A. ACIS CONTAM Version N0013

To illustrate the change that the new ACIS CONTAM N0013 model introduces, including the full mission timeline, we present the old model in Figs 2a (optical depth Tau at the center) and 2b (Tau from center to edge) against calibration data versus time derived from A1795 and Mkn 421 observations. For comparison, the new model is presented against the same calibration data in Figs 3a and 3b. Clearly the new model gives a much better representation of the contaminant layer depths in the recent two years.

supporting/center_jul19_120.gif
Fig. 2a: The layer depth versus time from the current N0012 CONTAM file in CalDB (trace), compared with "big dither" LETG/ACIS-S observations of Mkn 421 and imaging observations of A1795. It is clear there is a problem after early 2018.

supporting/center2edge_jul19_120.gif
Fig. 2b: Center-to-edge ratio comparison of the current N0012 CONTAM model (trace) compared to big dither Mkn 421 data and imaging A1795 data.

supporting/center_sep19_120.gif
Fig. 3a: Same as Fig 2a, but this time the trace is from the new CONTAM model in version N0013. This model becomes linear with time at about 2016 and thereafter, which fits the 2018-2019 much better without compromising earlier period performance.

supporting/center2edge_sep19_120.gif
Fig. 3b: Center-to-edge ratio comparison of the new N0013 CONTAM model (trace) compared to big dither Mkn 421 data and imaging A1795 data. Here the uniformity model for ACIS-S is much improved over the 2010-2019 period.

Having clarified the reason for updating the ACIS CONTAM model above, we now can illustrate how it changes the ACIS-I (Figs 4a & b) and ACIS-S (Figs 5a & b) aimpoint ARFs, respectively, with a sample of mission timeline dates. We have chosen mid-cycle dates (May 15) from years 2000, 2005, 2010, 2015, 2017, 2019, and predictively for 2022. For ACIS-I, there are some more significant low-energy changes for ealier dates versus the previous model, but these will be ineffectual because the ACIS-I EA is so small at these energies in any case. For ACIS-S, there is very little variation between the old and new models at early mission times, and a significant improvement in the model behavior (with respect to the actual contaminant build-up) in more recent years.

supporting/i3_eas_contam12_13.gif
Fig. 4a: ACIS-I3 aimpoint effective areas for mid-cycle 2000 (red-blue), 2005 (blue-cyan) , 2010 (majenta-yellow), 2015 (yellow-red), 2017 (teal), 2019 (orange), and 2022 (olive). The solid curves are with the N0013 model, and the dashes are derived with N0012.

supporting/pdiff_i3_eas_contam12_13.gif
Fig. 4b: ACIS-I3 EA percent differences derived from corresponding curves in Fig 3a. The color code is mid-cycle 2000 (red), 2005 (blue), 2010 (majenta), 2015 (yellow), 2017 (teal), 2019 (orange), and 2022 (olive).

supporting/s3_eas_contam12_13.gif
Fig. 5a: ACIS-S3 aimpoint effective areas for mid-cycle 2000 (red-blue), 2005 (blue-cyan) , 2010 (majenta-yellow), 2015 (yellow-red), 2017 (teal), 2019 (orange), and 2022 (olive). The solid curves are with the N0013 model, and the dashes are derived with N0012.

supporting/pdiff_s3_eas_contam12_13.gif
Fig. 5b: ACIS-S3 EA percent differences derived from corresponding curves in Fig 3a. The color code is mid-cycle 2000 (red), 2005 (blue), 2010 (majenta), 2015 (yellow), 2017 (teal), 2019 (orange), and 2022 (olive).