Abstract
The strain irreversibility cliff (SIC), marking the abrupt change of the intrinsic irreversible strain limit εirr,0 as a function of heat-treatment (HT) temperature θ in Nb3Sn superconducting wires made by the restacked-rod process (RRP®), is confirmed in various wire designs. It adds to the complexity of reconciling conflicting requirements on conductors for fabricating magnets. Those intended for the high-luminosity upgrade of the Large Hardon Collider (LHC) at the European Organization for Nuclear Research (CERN) facility require maintaining the residual resistivity ratio RRR of conductors above 150 to ensure stability of magnets against quenching. This benchmark may compromise the conductors’ mechanical integrity if their εirr,0 is within or at the bottom of SIC. In this coupled investigation of strain and RRR properties to fully assess the implications of SIC, we introduce an electro-mechanical stability criterion that takes into account both aspects. For standard-Sn billets, this requires a strikingly narrow HT temperature window that is impractical. On the other hand, reduced-Sn billets offer a significantly wider choice of θ, not only for ensuring that εirr,0 is located at the SIC plateau while RRR ≥ 150, but also for containing the strain-induced irreversible degradation of the conductor’s critical-current beyond εirr,0. This study suggests that HT of LHC magnets, made of reduced-Sn wires having a Nb/Sn ratio of 3.6 and 108/127 restacking architecture, be operated at θ in the range of 680 to 695 °C (when the dwell time is 48 hours).
Highlights
The strain irreversibility cliff (SIC), marking the abrupt change of the intrinsic irreversible strain limit εirr,[0] as a function of heat-treatment (HT) temperature θ in Nb3Sn superconducting wires made by
Measurements were made while the sample was immersed in liquid helium at a temperature of 4.04 to 4.07 K and subjected to an external magnetic field of 15 T provided by a superconducting solenoid
We coupled studies of Ic(ε) and those of RRR for various restacked-rod process (RRP) Nb3Sn billets heat-treated at different temperatures from 599 to 752 °C for 48 hours
Summary
The strain irreversibility cliff (SIC), marking the abrupt change of the intrinsic irreversible strain limit εirr,[0] as a function of heat-treatment (HT) temperature θ in Nb3Sn superconducting wires made by. The expected application of Nb3Sn superconducting wires in the high-luminosity (HL) upgrade of the Large Hadron Collider (LHC) at the European Organization for Nuclear Research (CERN) facility is dictated by the need for magnetic-field intensities in the range of 11 to 13 T, required to increase the rate of particle collisions at the ATLAS (A Toroidal LHC ApparatuS) and CMS (Compact Muon Solenoid) detectors of the LHC1,2. Such intensities are beyond the practical limits of Nb-Ti, which has been the main conductor for particle-accelerator technologies to date[3,4,5]. The upgrade project (HL-LHC) will consume about 30 tonnes of state-of-the art, very high critical-current density Jc, Nb3Sn wires[2], and will be a crucial step for testing the maturity of Nb3Sn technology for its potential usage to extend the field range to 16 T in future high-energy particle colliders1. (In this paper, wire is interchangeably referred to as conductor, billet, or strand)
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