Töpfer, J.J.TöpferHesse, J.J.HesseBierlich, S.S.BierlichBarth, S.S.BarthCapraro, B.B.CapraroRabe, T.T.RabeNagib-Zadeh, H.H.Nagib-ZadehBartsch, H.H.Bartsch2022-03-052022-03-052014https://publica.fraunhofer.de/handle/publica/24793910.2497/jjspm.61.S2142-s2.0-84988020193We have studied the integration of Ni-Cu-Zn ferrite spinels as well as substituted hexagonal Co2Y-and M-type ferrites into LTCC (Low Temperature Ceramic Co-firing) modules. The cofiring behavior and the magnetic properties of these materials were investigated and evaluated for multilayer applications. Ni-Cu-Zn ferrites exhibit permeabilities of m=300-500 for operating frequencies in the MHz range. Cu-substituted Y-type ferrites Ba2Co2-x-yZnxCuyFe12O22 in combination with sintering additives display sufficient shrinkage and densification at 900°C. A permeability of m=10 is observed; however, substituted Co2Y-type ferrites do not exhibit long-term stability at 900°C. Co/Ti-substituted M-type ferrites BaFe12-2yCoyTiyO19 (y=1.2) with planar magneto-crystalline anisotropy exhibit excellent soft magnetic behavior. Using sintering additives, complete densification is reached at 900°C and a permeability of m=15 and a resonance frequency of larger than 1 GHz are observed. Integration of ferrite multilayer inductor components into LTCC modules using free and constrained cofiring technologies is demonstrated.en620666journal article