Frontiers in Materials (Jan 2022)

Characterization of Heavily Irradiated Dielectrics for Pixel Sensors Coupling Insulator Applications

  • S. Bharthuar,
  • S. Bharthuar,
  • M. Golovleva,
  • M. Golovleva,
  • M. Bezak,
  • M. Bezak,
  • E. Brücken,
  • A. Gädda,
  • A. Gädda,
  • J. Härkönen,
  • J. Härkönen,
  • A. Karadzhinova-Ferrer,
  • A. Karadzhinova-Ferrer,
  • N. Kramarenko,
  • N. Kramarenko,
  • S. Kirschenmann,
  • S. Kirschenmann,
  • P. Koponen,
  • P. Luukka,
  • P. Luukka,
  • K. Mizohata,
  • J. Ott,
  • J. Ott,
  • E. Tuominen,
  • E. Tuominen

DOI
https://doi.org/10.3389/fmats.2021.769947
Journal volume & issue
Vol. 8

Abstract

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An increase in the radiation levels during the high-luminosity operation of the Large Hadron Collider calls for the development of silicon-based pixel detectors that are used for particle tracking and vertex reconstruction. Unlike the conventionally used conductively coupled (DC-coupled) detectors that are prone to an increment in leakage currents due to radiation, capacitively coupled (AC-coupled) detectors are anticipated to be in operation in future collider experiments suitable for tracking purposes. The implementation of AC-coupling to micro-scale pixel sensor areas enables one to provide an enhanced isolation of radiation-induced leakage currents. The motivation of this study is the development of new generation capacitively coupled (AC-coupled) pixel sensors with coupling insulators having good dielectric strength and radiation hardness simultaneously. The AC-coupling insulator thin films were aluminum oxide (Al2O3) and hafnium oxide (HfO2) grown by the atomic layer deposition (ALD) method. A comparison study was performed based on the dielectric material used in MOS, MOSFET, and AC-coupled pixel prototypes processed on high resistivity p-type Magnetic Czochralski silicon (MCz-Si) substrates. Post-irradiation studies with 10 MeV protons up to a fluence of 1015 protons/cm2 suggest HfO2 to be a better candidate as it provides higher sensitivity with negative charge accumulation on irradiation. Furthermore, even though the nature of the dielectric does not affect the electric field within the AC-coupled pixel sensor, samples with HfO2 are comparatively less susceptible to undergo an early breakdown due to irradiation. Edge-transient current technique (e-TCT) measurements show a prominent double-junction effect as expected in heavily irradiated p-type detectors, in accordance with the simulation studies.

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