I. Introduction

Ferroelectric field-effect transistor (FeFET) based on hafnium oxide has been studied for various memory-based applications, owing to its scalability, energy efficiency, and CMOS compatibility [1]–[5]. However, its accurate device physics is still not understood well, even though it is necessarily required for modeling the device, improving device performance, and constructing process design kit (PDK) to use in the industry. Many studies have focused on the interplay between polarization and charge trapping to understand the mechanism due to the high surface charge density (~10¹⁴ cm⁻²) of the spontaneous polarization in the ferroelectric layer [6], [7]. Nevertheless, the conventional methodology of measuring polarization switching has the fundamental limitation because it works only with a ferroelectric capacitor, not with FeFET. Thus, most previous studies have not directly captured the polarization value in FeFET and have not carefully studied the device based on charge analysis.