The hexagonal ferrite materials such as Ba- and Sr-Fe12O19 show strong ferromagnetic absorption in the 40-60 GHz range . However, in the higher millimeter wave frequency range beyond 60 GHz, the natural ferromagnetic ferrite materials with high performance are lacking due to the limitation of material science and synthetic complexity . The synthesis of single phase of ε-iron oxide (ε-Fe2O3) enables the development of magnetic materials which have natural ferromagnetic resonance from 50 to 200 GHz . Among the four polymorphs of α-, ß-, γ-, ε-Fe2O3, the ß- and ε-Fe2O3 are rare and must be synthesized in the laboratory . The pure ε-Fe2O3 shows the largest coercive field value (Hc) of 20 kOe among metal oxide-based magnets at room temperature . Multiple factors contribute to the gigantic Hc in ε-Fe2O3 . One is the small ε-Fe2O3 crystal size . A large Hc value is expected when the particle size is sufficiently small to form a single magnetic domain . A particle size of ca . 100 nm in the material is suitable to realize a single magnetic domain . Another is the intrinsic magnetic property of the ε-Fe2O3 phase . The Hc value depends on the magnetocrystalline anisotropy constant (K) and saturated magnetization (Ms), i .e ., Hc K/Ms . Anaysis of the initial magnetization process estimates the K value in the present material as 2-4 x 106 erg cm-3, which greatly exceeds the K values of γ-Fe2O3 (ca . 104 erg cm-3) and α-Fe2O3 (ca . 105 erg cm-3) . In addition, the observed Ms value is small, 15 emu g-1 (15 A m2 kg-1) at 7 .0 T . Therefore, it is concluded that the large Hc value of 20 kOe is due to (1) the suitable nanoscale size of particles that form a single magnetic domain and (2) the large K and small Ms values of ε-Fe2O3 . Such high Hc is very attractive in millimeter applications . By employing metal substitution method, the metal-substituted ε-iron oxide can exhibit an adjustable ferromagnetic resonant frequency at 35-182 GHz depending on the degree of metal substitutio...