Abstract
Future applications requiring high magnetic fields, such as the proposed Future Circular Collider, demand a substantially higher critical current density, J c, at fields ≥16 T than is presently available in any commercial strand, so there is a strong effort to develop new routes to higher J c Nb3Sn. As a consequence, evaluating the irreversibility field (Hirr ) of any new conductor to ensure reliable performance at these higher magnetic fields becomes essential. To predict the irreversibility field for Nb3Sn wires, critical current measurements, I c, are commonly performed in the 12-15 T range and the Kramer extrapolation is used to predict higher field properties. The Kramer extrapolation typically models the contribution only for sparse grain boundary pinning, yet Nb3Sn wires rely on a high density of grain boundaries to provide the flux pinning that enables their high critical current density. However, whole-field range VSM measurements up to 30 T recently showed for Nb3Sn RRP® wires that the field dependence of the pinning force curve significantly deviates from the typical grain boundary shape, leading to a 1-2 T overestimation of Hirr when extrapolated from the typical mid-field data taken only up to about 15 T. In this work we characterized a variety of both RRP® and PIT Nb3Sn wires by transport measurements up to 29 T at the Laboratoire National des Champs Magnétiques Intenses (LNCMI), part of the European Magnetic Field Laboratory in Grenoble, to verify whether or not such overestimation is related to the measurement technique and whether or not it is a common feature across different designs. Indeed we also found that when measured in transport the 12-15 T Kramer extrapolation overestimates the actual Hirr in both types of conductor with an inaccuracy of up to 1.6 T, confirming that high field characterization is a necessary tool to evaluate the actual high field performance of each Nb3Sn wire.
Highlights
The 100 TeV Future Circular Collider (FCC) envisioned at CERN will require a large number of Nb3Sn bending magnets which will need to operate in the 16 T range [1,2]
Nb3Sn wires have been characterized by measuring Jc from 12 to 15 T using the Kramer extrapolation to predict the irreversibility field
As we are considering Nb3Sn for magnets operating at up to about 20 T, it is important to know the true high field properties to fully understand their operating margins. To this end it was recently found by Tarantini et al [11] that this commonly used mid-field Kramer extrapolation consistently over predicts Hirr by more than 2 T using Vibrating Sample Magnetometry (VSM) up to 30 T
Summary
The 100 TeV Future Circular Collider (FCC) envisioned at CERN will require a large number of Nb3Sn bending magnets which will need to operate in the 16 T range [1,2]. Only two wire manufacturing processes have demonstrated the potential to bring Nb3Sn into this high field operation range: the Rod Restack Process (RRP®) produced by Bruker OST [3], and the Powder In Tube (PIT) technique produced by Bruker EAS [4,5,6]. Published under licence by IOP Publishing Ltd. 1559 (2020) 012062 doi:10.1088/1742-6596/1559/1/012062 chemistry, architecture and heat treatment of these conductors, the Jc appears to be limited well below the desired 1,500 A/mm (16 T, 4.2 K) demanded for FCC [7]. In an effort to push Nb3Sn superconducting technology to its limits, the conductor community has been focussing R&D towards the introduction of additional pinning centers (APC) to increase Jc in the superconducting transport layer, and to shift the maximum of the pinning force curve to higher fields. There are multiple groups working on variants of the PIT process to introduce additional pinning centers
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