This work investigates whether quantum entanglement assistance alone can yield significant and robust Shannon capacity gains in classical multiple-access channels where transmitters possess causal channel state information at the transmitter (CSIT). By integrating information-theoretic analysis, quantum entanglement resource modeling, and capacity computation techniques under causal CSIT, the study establishes—for the first time—that, with fixed input and output alphabets, entanglement assistance enables a capacity gain that grows exponentially with the number of users. Moreover, this gain becomes unbounded as the state alphabet size increases. In binary systems, capacity improvements exceeding 21-fold and 88-fold are achieved for five- and seven-user scenarios, respectively, and the exponential advantage persists even when each entangled qubit undergoes complete depolarization with probability 30%.

Quantum entanglement assistance is known to improve the Shannon capacity of classical communication networks but the largest gains noted thus far are rather modest (less than 6%), motivating the question: are large capacity gains ever possible? It is shown in this work that in the presence of causal channel state information at the transmitters, quantum entanglement assistance provides a multiplicative capacity advantage that grows exponentially with the number of users K for certain classical K-user multiple access channels with fixed size (binary) alphabet for inputs, outputs and states. Similarly, in the presence of causal channel state information at the transmitters, quantum entanglement assistance is shown to provide a multiplicative capacity advantage that is unbounded as the size of the state alphabet grows, while the number of users (K=3) and the input and output alphabet (binary) are held fixed. Even with only a few users and small alphabet sizes, substantial multiplicative gains in capacity are found, e.g., with binary inputs, outputs and states, multiplicative gains by factors exceeding 21 and 88 are noted with K=5 and K=7 users, respectively. The gains are robust in the sense that they persist even with noisy quantum resources, e.g., an exponential (in K) capacity advantage from quantum entanglement assistance remains available even if each entangled qubit independently depolarizes completely with probability $\approx$ 30%. The gains are based on quantum entanglement assistance provided only to the transmitters.