Researchers have made significant progress in developing fault-tolerant architectures for neutral atom systems, which can be used to achieve quantum advantage in applications such as quantum dynamics simulations. These architectures prioritize spatial efficiency and low qubit overhead, incorporating efficient methodologies like transversal-based gates and extractor-based gates. By optimizing quantum error correction codes and gate implementations, scientists can create more robust and reliable quantum systems. The development of early fault-tolerant architectures is crucial for the advancement of quantum computing, as it enables the creation of more complex and powerful quantum systems. This, in turn, narrows the timeline for migrating to post-quantum cryptography, increasing the urgency for planning and implementation of quantum-resistant cryptographic systems1. As a result, practitioners must prioritize quantum-resistant cryptography planning to stay ahead of the rapidly advancing quantum computing landscape.