What question did this study set out to answer?

The study aims to develop a solid-state superconducting axial flux motor with efficient cooling.

March 5, 2026Open Access

Topology of a Solid-State Superconducting Axial Flux Motor via Self-Excited Cascaded Magnetocaloric Cryocooling

Key Points

The study aims to develop a solid-state superconducting axial flux motor with efficient cooling.
Introduced a self-excited motor topology using a spatially cascaded magnetocaloric stator disk.
Utilized ErCo2 for deep-cryogenic heat extraction and La-Fe-Si for ambient heat rejection.
Engineered the design to operate without fluid cryogens.
Achieved zero DC resistance in the motor design.
Maintained superconducting coils below critical temperature of 77 K.
Reduced complexity and mass associated with traditional cryogenic cooling systems.

Abstract

High-temperature superconducting (HTS) motors promise zero DC resistance (R = 0), but their application is heavily constrained by the mass and complexity of cryogenic liquid cooling systems (e.g., liquid nitrogen/helium pumps). Building upon our previously proposed AF-MCE architecture, this paper introduces a V3.0 paradigm: a self-excited, solid-state superconducting motor topology. By engineering a spatially cascaded magnetocaloric stator disk—utilizing ErCo2 for deep-cryogenic heat extraction and La-Fe-Si for ambient heat rejection—this architecture leverages the motor’s in trinsic alternating magnetic field to maintain HTS coils (e.g., YBCO) below their critical temperature Tc = 77 K without any fluid cryogens.

Topology of a Solid-State Superconducting Axial Flux Motor via Self-Excited Cascaded Magnetocaloric Cryocooling

Key Points

Abstract

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