Accelerating Fault-Tolerant Quantum Computation with Good qLDPC Codes

We propose a fault-tolerant quantum computation scheme that is broadly applicable to quantum low-density parity-check (qLDPC) codes. The scheme achieves constant qubit overhead and a time overhead of $O\(d^{a+o(1\)})$ for any $[[n,k,d]]$ qLDPC code with constant encoding rate and distance $d = Ω\(n^{1/a}\)$. For good qLDPC codes, the time overhead is minimized and reaches $O\(d^{1+o(1\)})$. In contrast, code surgery based on gauging measurement and brute-force branching requires a time overhead of $O\(dw^{1+o(1\)})$, where $d\leq w\leq n$. Thus, our scheme is asymptotically faster for all codes with $a < 2$. This speedup is achieved by developing techniques that enable parallelized code surgery under constant qubit overhead and leverage classical locally testable codes for efficient resource state preparation. These results establish a new paradigm for accelerating fault-tolerant quantum computation on qLDPC codes, while maintaining low overhead and broad applicability.