Organic magnetoresistance and spin diffusion in organic semiconductor thin film devices

We review recent work in the field of organic spintronics, focusing on our own contributions to this field. There are two principle magnetoresistance effects that occur in organic devices. (i) Organic magnetoresistance (OMAR), which occurs in nonmagnetic organic semiconductor devices. For example, in devices made from the prototypical small molecule Alq3 OMAR reaches values of 10% or more at room temperature. (ii) Organic spin-valve effects that occur in devices that employ ferromagnetic electrodes for spin-polarized current injection and detection. We undertake an analysis of these two types of magnetoresistance with the goal of identifying the dominant spin-scattering mechanism. Analysis of OMAR reveals that hyperfine coupling is the dominant spin-coupling mechanism. Spinorbit coupling, on the other hand, is important only in organic semiconductor materials containing heavy atoms. We explore the reasons why spinorbit coupling is relatively unimportant in hydrocarbon materials. Next, we present a theory for spin diffusion in disordered organic semiconductors based on hyperfine coupling, taking into account a combination of incoherent carrier hopping and coherent spin precession in the random hyperfine magnetic fields. We compare our findings with experimental values for the spin-diffusion length. Finally, we demonstrate a criterion that allows the determination whether the organic spin-valves operate in the tunneling or injection regimes. ((c) 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim)