Colossal proximity effect in a superconducting triplet spin valve based on halfmetallic ferromagnetic CrO2

Abstract

Ferromagnets can sustain supercurrents through the formation of equal spin triplet Cooper pairs and the mechanism of odd-frequency pairing. Since such pairs are not broken by the exchange energy of the ferromagnet, superconducting triplet correlations are long-ranged and spin-polarized, with promises for superconducting spintronics devices. The main challenge is to understand how triplets are generated at the superconductor (S)/ ferromagnet (F) interface. Here we use the concept of a so-called triplet spin valve (TSV) to investigate the conversion of singlets in a conventional superconductor to triplets in the halfmetallic ferromagnet CrO2. TSV's are composed of two ferromagnetic layers (separated by a thin normal metal (N) layer) and a superconductor (F1/N/F2/S). The package F1/N/F2 generates triplets in F1 when the magnetization directions of the F1,2-layers are not collinear. This drains singlet pairs from the S-layer, and triplet generation is therefore signalled by a decrease of the critical temperature Tc. Recently, experiments with TSV's were reported with Co draining layers, using in-plane fields, and finding Tc-shifts up to 100~mK. Using CrO2 instead of Co and rotating a magnetic field from in-plane to out-of-plane, we find strong Tc variations of almost a Kelvin up to fields of the order of a Tesla. Such strong drainage is consistent with the large lengths over which supercurrents can flow in CrO2, which are significantly larger than in conventional ferromagnets. Our results point to the special interest of halfmetals for superconducting spintronics.