We show that the cooperative reinforcement between hydrogen bonds in guanine quartets is not caused by resonance‐assisted hydrogen bonding (RAHB). This follows from extensive computational analyses of guanine quartets (G4) and xanthine quartets (X4) based on dispersion‐corrected density functional theory (DFT‐D). Our investigations cover the situation of quartets in the gas phase, in aqueous solution as well as in telomere‐like stacks. A new mechanism for cooperativity between hydrogen bonds in guanine quartets emerges from our quantitative Kohn–Sham molecular orbital (MO) and corresponding energy decomposition analyses (EDA). Our analyses reveal that the intriguing cooperativity originates from the charge separation that goes with donor–acceptor orbital interactions in the σ‐electron system, and not from the strengthening caused by resonance in the π‐electron system. The cooperativity mechanism proposed here is argued to apply, beyond the present model systems, also to other hydrogen bonds that show cooperativity effects. Separation leads to cooperation: Quantum chemical analyses show that telomere structures receive additional stabilization from cooperativity effects in guanine quartets (see graphic). This cooperativity derives directly from the charge separation across guanine bases, induced by the unidirectional donor–acceptor orbital interactions in the hydrogen bonds.