Flexible epsilon-Fe2O3-terephthalate thin-film magnets through ALD/MLD.

Pliable and lightweight thin-film magnets performing at room temperature are indispensable ingredients of the next-generation flexible electronics. However, conventional inorganic magnets based on f-block metals are rigid and heavy, while the emerging organic/molecular magnets are yet inferior regarding their magnetic characteristics. Here we fuse the best features of the two worlds, by tailoring epsilon-Fe2O3-terephthalate superlattice thin films with inbuilt flexibility due to the thin organic layers intimately embedded within the ferrimagnetic epsilon-Fe2O3 matrix; these films are also sustainable as they do not contain rare heavy metals. The films are grown with sub-nm scale accuracy from gaseous precursors using the atomic/molecular layer deposition (ALD/MLD) technique. Tensile tests confirm the expected increased flexibility with increasing organic content reaching a threefold decrease in critical bending radius (2.4+/-0.3 mm) as compared to epsilon-Fe2O3 thin film (7.7+/-0.3 mm). Most remarkably, these hybrid epsilon-Fe2O3-terephthalate films do not compromise the exceptional intrinsic magnetic characteristics of the epsilon-Fe2O3 phase, in particular the ultra-high coercive force (~2 kOe) even at room temperature.