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Influence of Biaxial Strain and Interfacial Layer Growth on Ferroelectric Wake-Up and Phase Transition Fields in ZrO 2 .

Bohan XuRichard GanserKristina M HolsgroveXuetao WangPramoda VishnumurthyThomas MikolajickUwe SchroederAlfred KerschPatrick D Lomenzo
Published in: ACS applied materials & interfaces (2024)
Investigations on fluorite-structured ferroelectric HfO 2 /ZrO 2 thin films are aiming to achieve high-performance films required for memory and computing technologies. These films exhibit excellent scalability and compatibility with the complementary metal-oxide semiconductor process used by semiconductor foundries, but stabilizing ferroelectric properties with a low operation voltage in the as-fabricated state of these films is a critical component for technology advancement. After removing the influence of interfacial layers, a linear correlation is observed between the biaxial strain and the electric field for transforming the nonferroelectric tetragonal to the ferroelectric orthorhombic phase in ZrO 2 thin films. This observation is supported by applying the principle of energy conservation in combination with ab initio and molecular dynamics simulations. According to the simulations, a rarely reported Pnm2 1 orthorhombic phase may be stabilized by tuning biaxial strain in the ZrO 2 films. This study demonstrates the significant influence of interfacial layers and biaxial strain on the phase transition fields and shows how strain engineering can be used to improve ferroelectric wake-up in ZrO 2 .
Keyphrases
  • molecular dynamics simulations
  • room temperature
  • ionic liquid
  • molecular docking
  • electron transfer
  • working memory
  • perovskite solar cells
  • neural network