Warm Spitzer IRAC Photometry: dependencies on observing mode and exposure time

TL;DR

This study analyzes how observing mode and exposure time affect Spitzer IRAC photometry, revealing small but significant flux differences that are crucial for high-precision measurements.

Contribution

It provides a detailed quantification of flux dependencies on observing strategies, highlighting subtle effects relevant for precise photometric studies.

Findings

Full array observations yield slightly lower fluxes than subarray.

Longer exposure times slightly reduce measured fluxes.

No significant difference between dithered and staring modes.

Abstract

We investigate differences in Spitzer/IRAC 3.6 and 4.5micron photometry that depend on observing strategy. Using archival calibration data we perform an in-depth examination of the measured flux densities ("fluxes") of ten calibration stars, observed with all the possible observing strategies. We then quantify differences in the measured fluxes as a function of 1) array mode (full or subarray), 2) exposure time, and 3) dithering versus staring observations. We find that the median fluxes measured for sources observed using the full array are 1.6% and 1% lower than those observed with the subarray at [3.6] and [4.5], respectively. Additionally, we found a dependence on the exposure time such that for [3.6] observations the long frame times are measured to be lower than the short frame times by a median value of 3.4% in full array and 2.9% in subarray. For [4.5] observations the longer frame times are 0.6% and 1.5% in full and subarray respectively. These very small variations will likely only affect science users who require high-precision photometry from multiple different observing modes. We find no statistically significant difference for fluxes obtained with dithered and staring-modes. When considering all stars in the sample, the fractional well depth of the pixel is correlated with the different observed fluxes. We speculate the cause to be a small non-linearity in the pixels at the lowest well depths where deviations from linearity were previously assumed to be negligible.