Toward fast low-noise low-power digital CCDs for Lynx and other high-energy astrophysics missions

Future X-ray missions such as Lynx require large-format imaging detectors with performance at least as good as the best current-generation devices but with much higher readout rates. We are investigating a Digital CCD detector architecture, under development at MIT Lincoln Laboratory, for use in such missions. This architecture features a CMOS-compatible detector integrated with parallel CMOS signal processing chains. Fast, low-noise amplifiers and highly parallel signal processing provide the high frame-rates required. CMOS-compatibility of the CCD provides low-power charge transfer and signal processing. We report on the performance of CMOS-compatible test CCDs read at rates up to 5 Mpix s−1 (50 times faster than Chandra ACIS CCDs), with transfer clock swings as low as ±1.5 V (power/area < 10% of that of ACIS CCDs). We measure read noise below 6 electrons RMS at 2.5 MHz and X-ray spectral resolution better than 150 eV FWHM at 5.9 keV for single-pixel events. We discuss expected detector radiation tolerance at these relatively high transfer rates. We point out that the high pixel ’aspect ratio’ (depletion-depth : pixel size ≈ 9 : 1) of our test devices is similar to that expected for Lynx detectors, and illustrate some of the implications of this geometry for X-ray performance and noise requirements.

[1]  B. LaMarr,et al.  Anomalous annealing of a high-resistivity CCD irradiated at low temperature , 2005, IEEE Transactions on Nuclear Science.

[2]  Norbert Meidinger,et al.  The wide field imager instrument for Athena , 2016, Astronomical Telescopes + Instrumentation.

[3]  Marshall W. Bautz,et al.  The high definition x-ray imager (HDXI) instrument on the Lynx X-ray Surveyor , 2018, Astronomical Telescopes + Instrumentation.

[4]  H. Uchiyama,et al.  Mitigating CCD radiation damage with charge injection: first flight results from Suzaku , 2007, SPIE Optical Engineering + Applications.

[5]  Richard L. Kelley,et al.  Special Section Guest Editorial: The Hitomi X-ray Observatory , 2018 .

[6]  Kazumi Wada,et al.  Evaluation of irradiation-induced deep levels in Si , 2000, SPIE Optics + Photonics.

[7]  Pavel Hazdra,et al.  Accurate Identification of Radiation Defect Profiles in Silicon after Irradiation with Protons and Alpha-Particles in the MeV Range , 2003 .

[8]  Mark Clampin,et al.  Transiting Exoplanet Survey Satellite (TESS) , 2014, Astronomical Telescopes and Instrumentation.

[9]  David N. Burrows,et al.  Recent X-ray hybrid CMOS detector developments and measurements , 2017, Optical Engineering + Applications.

[10]  B. LaMarr,et al.  CCD Charge Injection Structure at Very Small Signal Levels , 2008, IEEE Transactions on Electron Devices.

[11]  William W. Zhang,et al.  Lynx Observatory and Mission Concept Status , 2017 .

[12]  Hirofumi Yamashita,et al.  A highly sensitive on-chip charge detector for CCD area image sensor , 1991 .

[13]  Gregory Y. Prigozhin,et al.  The effects of charge diffusion on soft x-ray response for future high-resolution imagers , 2018, Astronomical Telescopes + Instrumentation.

[14]  Barry E. Burke,et al.  CCD soft X-ray imaging spectrometer for the ASCA satellite , 1994 .

[15]  Didier Barret,et al.  Athena: ESA's X‐ray observatory for the late 2020s , 2017 .

[16]  Barry E. Burke,et al.  Orthogonal transfer arrays for the Pan-STARRS gigapixel camera , 2007, Electronic Imaging.

[17]  Mark Clampin,et al.  Transiting Exoplanet Survey Satellite , 2014, 1406.0151.

[18]  S. D. Brotherton,et al.  Defect production and lifetime control in electron and γ‐irradiated silicon , 1982 .

[19]  Stephen M. Amato,et al.  Advancing the technology of monolithic CMOS detectors for use as x-ray imaging spectrometers , 2017, Optical Engineering + Applications.