Improved Bounds for Pure Quantum Locally Recoverable Codes Enable Explicit Constructions

Quantum data storage demands increasingly robust error correction, and researchers are now focusing on locally recoverable codes as a promising solution for large-scale systems. Yang Li, Shitao Li, and Gaojun Luo from Nanjing University of Aeronautics and Astronautics, alongside San Ling from Nanyang Technological University and VinUniversity, have significantly advanced this field by developing tighter boundaries for the performance of pure quantum locally recoverable codes. Their work overcomes limitations in existing theoretical frameworks, enabling the construction of demonstrably superior codes, and importantly, revealing that well-established classical error-correcting codes, such as Hamming, GRM, and Solomon-Stiffler codes, can serve as the foundation for these quantum systems. This breakthrough unlocks the potential for substantially longer and more reliable quantum storage, exceeding the capabilities of previously known designs and paving the way for practical applications in future quantum technologies. Quantum and Classical Locally Recoverable Codes This work details research on locally recoverable codes (LRCs), both classical and quantum, focusing on improving data reliability and efficient recovery in storage systems. A significant portion explores quantum LRCs, investigating methods for constructing codes with locality properties similar to their classical counterparts, and optimizing their design using algebraic structures. Researchers concentrate on optimizing code parameters, such as minimum distance and locality, with applications in quantum memories and erasure correction. Tighter Bounds for Quantum Locally Recoverable Codes Scientists have significantly advanced the development of quantum locally recoverable codes (qLRCs), crucial for reliable data storage in quantum systems. This work focuses on improving the construction and understanding of these codes, particularly those derived from the Hermitian construction, and establishes new mathematical bounds that define the limits of performance for pure qLRCs. These tighter bounds enable the design of more efficient and powerful quantum error-correcting codes by rigorously analyzing existing bounds and extending the Griesmer and Plotkin bounds from classical coding theory to the quantum realm.

Tighter Bounds Enable Longer Locally Recoverable Codes Scientists have achieved significant advancements in the construction of locally recoverable codes (qLRCs), demonstrating improvements in data storage applications. The research focuses on pure qLRCs derived from the Hermitian construction, establishing new bounds that are demonstrably tighter than previously known limitations. These tighter bounds enable the identification of optimal qLRCs with substantially larger code lengths than those previously achieved, and demonstrate that classical quantum error-correcting codes, including quantum Hamming, generalized Reed-Muller, and Solomon-Stiffler codes, can be utilized to generate pure qLRCs with explicit parameters.

Optimal Locally Recoverable Codes Discovered Researchers have made significant advances in the construction of locally recoverable codes, a type of error-correcting code with applications in large-scale data storage.

The team developed new mathematical bounds that more accurately assess the potential performance of these codes, allowing for the identification of more efficient designs. Building on Hermitian construction techniques, they demonstrated that several well-established classical codes, including Hamming, GRM, and Solomon-Stiffler codes, can be adapted to create pure locally recoverable codes with explicit, well-defined parameters, resulting in the discovery of numerous infinite families of optimal locally recoverable codes exceeding the performance of previously known designs in terms of code length. 👉 More information 🗞 Improved bounds and optimal constructions of pure quantum locally recoverable codes 🧠 ArXiv: https://arxiv.org/abs/2512.07256 Tags: Rohail T. As a quantum scientist exploring the frontiers of physics and technology. My work focuses on uncovering how quantum mechanics, computing, and emerging technologies are transforming our understanding of reality. I share research-driven insights that make complex ideas in quantum science clear, engaging, and relevant to the modern world. Latest Posts by Rohail T.: Simulating General Noise Nearly As Cheaply As Pauli Noise Enables Efficient Clifford Circuit Performance Analysis December 10, 2025 Hartree-fock and Kohn-Sham Equations Reveal Non-Hermitian Solutions and Electron Density Transfer December 10, 2025 Oxtal: 100M Parameter Diffusion Model Predicts Organic Crystal Structures from 2D Graphs December 10, 2025