C.L. Howe scite author profile

The interaction between a heavy ion and the overlayer materials in an integrated circuit may result in a nuclear reaction. This reaction leads to a charge generation profile that is substantially altered from the profile generated during a direct ionization event. In this work, nuclear reactions are integrated into the modeling of the SEU response of an SRAM cell using GEANT4-based simulations. The simulated transient response is compared to the response obtained using a typical heavy ion model that includes only direct ionization.

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Comparison of Measured Dark Current Distributions With Calculated Damage Energy Distributions in HgCdTe

Marshall

Howe

et al. 2007

IEEE Trans. Nucl. Sci.

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Abstract-This paper presents a combined Monte Carlo and analytic approach to the calculation of the pixel-to-pixel distribution of proton-induced damage in a HgCdTe sensor array and compares the results to measured dark current distributions after damage by 63 MeV protons. The moments of the Coulombic, nuclear elastic and nuclear inelastic damage distributions were extracted from Monte Carlo simulations and combined to form a damage distribution using the analytic techniques first described in [I]. The calculations show that the high energy recoils from the nuclear inelastic reactions (calculated using the Monte Carlo code MCNPX [2]) produce a pronounced skewing of the damage energy distribution. While the nuclear elastic component (also calculated using the MCNPX) contributes only a small fraction of the total nonionizing damage energy, its inclusion in the shape of the damage across the array is significant. The Coulombic contribution was calculated using MRED 13-51, a Geant4 [4,6] application. The comparison with the dark current distribution strongly suggests that mechanisms which are not linearly correlated with nonionizing damage produced according to collision kinematics are responsible for the observed dark current increases. This has important implications for the process of predicting the on-orbit dark current response of the HgCdTe sensor array.

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Distribution of Proton-Induced Transients in Silicon Focal Plane Arrays

Howe

Weller

Reed

et al. 2007

IEEE Trans. Nucl. Sci.

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C.L. Howe

The contribution of nuclear reactions to heavy ion single event upset cross-section measurements in a high-density SEU hardened SRAM

Role of heavy-ion nuclear reactions in determining on-orbit single event error rates

Simulating Nuclear Events in a TCAD Model of a High-Density SEU Hardened SRAM Technology

Comparison of Measured Dark Current Distributions With Calculated Damage Energy Distributions in HgCdTe

Distribution of Proton-Induced Transients in Silicon Focal Plane Arrays

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