What question did this study set out to answer?

The aim is to develop reliable non-volatile memory devices that can operate at high temperatures.

March 28, 2026

High-temperature memristors enabled by interfacial engineering

Key Points

The aim is to develop reliable non-volatile memory devices that can operate at high temperatures.
Fabricated graphene-based memristors using HfO x and tungsten layers.
Evaluated performance at temperatures up to 700 °C.
Used transmission electron microscopy to investigate material properties after high-temperature exposure.
Conducted first-principles calculations to analyze thermal stability mechanisms.
Memristors operated reliably at temperatures up to 700 °C.
Achieved an ON/OFF current ratio greater than 10^3.
Demonstrated data retention exceeding 50 hours and endurance over 10^9 switching cycles.
Less W diffusion into the graphene-based devices compared to conventional platinum-based devices.

Abstract

Non-volatile memories (NVM) that operate reliably at high temperature are essential for electronics in extreme environments. Here, we reported graphene (Gra)/HfO x /tungsten (W) memristors that operated reliably up to 700 °C with an ON/OFF current ratio >10 3 , data retention >50 hours and endurance >10 9 switching cycles. Transmission electron microscopy (TEM) revealed significant W diffusion into the inert platinum (Pt) electrode of conventional Pt/HfO x /W memristors after high-temperature annealing, which was an effect responsible for the thermal failure of conventional devices but not observed in Gra/HfO X /W devices. First-principles calculations attributed the enhanced thermal stability to weaker W adsorption and higher surface diffusion barriers on graphene than metals like Pt. These results underscore the critical role of interfacial engineering and potential of 2D materials in enabling reliable high-temperature NVM technologies.

Bookmark

High-temperature memristors enabled by interfacial engineering

Key Points

Abstract

Cite This Study