Quantum computers promise to solve challenging computational problems more efficiently than conventional computers. Quantum algorithms demonstrating small instances of challenging computations, such as factorization, solving quantum chemistry problems, finding solutions to optimization problems, or quantum simulations, have been realized using noisy intermediate scale quantum (NISQ) hardware. However, it has become evident that fault-tolerant quantum computation will be required for addressing problems on relevant scales of complexity and for building universal quantum computers. In the SuperMOOSE project, a team of scientists from ETH Zurich (Switzerland), MIT (USA), FZ Juelich (Germany), Universite de Sherbrooke (Canada), Zurich Instruments (Switzerland) and Atlantic Quantum (USA) plan to advance the realization of error corrected-quantum hardware by entangling two logical qubits and teleporting the quantum state of one logical qubit to a second one. The team combining the efforts of two leading experimental labs exploring superconducting quantum electronic circuits, two leaders in theoretical work on concepts of quantum error correction, fault-tolerance and the theory of superconducting quantum circuits with a leading SME developing both control electronics hard- and software and a dynamic quantum computing startup is well set to tackle this challenge.