Researchers have discovered a novel approach to creating quantum many-body scars, leveraging the intrinsic soliton structure of the Rule-54 quantum cellular automaton. This breakthrough enables the coexistence of nonthermal eigenstates with a thermalizing many-body spectrum, effectively introducing a controlled form of weak ergodicity breaking. By exploiting the hard-core dimer sector of Rule 54, scientists can construct an exactly translatable protected skeleton, facilitating the creation of exact scars at the qubit level1. The introduction of this qubit-level route has significant implications for the field of quantum physics, as it provides a new framework for understanding and manipulating quantum many-body systems. The discovery of Fibonacci many-body scars in this context further highlights the potential for complex, structured eigenstates to emerge in these systems. This matters to practitioners because it opens up new avenues for exploring and controlling quantum behavior, with potential applications in quantum computing and simulation.