Abstract

Abstract Constructing built‐in electric fields is a proven method to enhance dielectric loss mechanisms by amplifying interfacial polarization. However, a single built‐in electric field is often insufficient for significantly improving electromagnetic (EM) polarization loss. To address this, dielectric ecosystems are developed utilizing an anion injection strategy to regulate work function differences. Through first‐principles calculations, the directional transfer of space charges at multi‐heterogeneous interfaces is visualized. The resulting work function differences spontaneously establish a dual built‐in electric field (DBIEF) structure, which substantially enhances EM polarization loss and EM wave absorption capabilities. Furthermore, an equivalent circuit model elucidates the competition between polarization and conduction species in the EM loss mechanism. This competition results in exceptional EM wave absorption performance, achieving a minimum reflection loss ( RL min ) of −58.71 dB and an effective absorption bandwidth (EAB) of 7.92 GHz. Computer simulation technology demonstrates a maximum radar cross‐section (RCS) reduction of 39.18 dB·m 2 . Additionally, the unique hollow‐truncated‐pyramid metamaterial design exhibits high incidence angle insensitivity (60°) over 2–38 GHz, and significant broadband absorption across 2–40 GHz. This comprehensive work offers novel insights into the structural design of EM nanomaterials and introduces a new dielectric ecosystem to elucidate the DBIEF loss mechanism for efficient EM wave absorption.