Abstract
Flexible memory can enable industrial, automobile, space, and smart grid centered harsh/extreme environment focused electronics application(s) for enhanced operation, safety, and monitoring where bent or complex shaped infrastructures are common and state-of-the-art rigid electronics cannot be deployed. Therefore, we report on the physical-mechanical-electrical characteristics of a flexible ferroelectric memory based on lead zirconium titanate as a key memory material and flexible version of bulk mono-crystalline silicon (100). The experimented devices show a bending radius down to 1.25 cm corresponding to 0.16% nominal strain (high pressure of ∼260 MPa), and full functionality up to 225°C high temperature in ambient gas composition (21% oxygen and 55% relative humidity). The devices showed unaltered data retention and fatigue properties under harsh conditions, still the reduced memory window (20% difference between switching and non-switching currents at 225°C) requires sensitive sense circuitry for proper functionality and is the limiting factor preventing operation at higher temperatures.
Cite
CITATION STYLE
Ghoneim, M. T., & Hussain, M. M. (2015). Study of harsh environment operation of flexible ferroelectric memory integrated with PZT and silicon fabric. Applied Physics Letters, 107(5). https://doi.org/10.1063/1.4927913
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