What question did this study set out to answer?

This research aims to investigate how temperature and magnetic fields affect the electrical conductivity in two-dimensional electronic systems.

March 25, 2026

Temperature and Magnetic Field Effects on the Conductivity Behavior in Two-Dimensional Electronic Systems

Key Points

This research aims to investigate how temperature and magnetic fields affect the electrical conductivity in two-dimensional electronic systems.
Analyzed longitudinal conductivity in 2D electronic systems
Considered classical Drude and quantum effects
Examined weak localization, anti-weak localization, and electron-electron interactions
Magnetic fields and temperature significantly impact conductivity behavior
Quantum effects alter the conductivity at low temperatures
Findings highlight the role of quantum corrections in transport phenomena

Abstract

The electrical conductivity in two-dimensional (2D) electronic systems is strongly influenced by temperature and applied magnetic fields. Beyond the classical Drude description, quantum effects such as weak localization (WL), anti-weak localization (AWL), and electron-electron interactions (EEI) significantly modify the conductivity at low temperatures. This work analyzes the combined impact of magnetic field and temperature on longitudinal conductivity in 2D systems, highlighting the underlying mechanisms and corresponding quantum corrections. The study demonstrates that magnetic field and temperature act as complementary probes for quantum corrections in 2D transport.

Temperature and Magnetic Field Effects on the Conductivity Behavior in Two-Dimensional Electronic Systems

Key Points

Abstract

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