A combination of experimental trapped-ion mass spectrometric studies and computational chemistry has been used in the present work to assess the intrinsic properties of the potassiated 9-ethylguanine (9eG) self-assembled quadruplex, K2(9eG)122+, in the gas phase. Infrared multiple photon dissociation (IRMPD) spectroscopy in the N-H/C-H stretching region (2700-3800 cm-1) revealed that this G-quadruplex is a sandwich-type structure with two G-tetrads sandwiching each of the two K+, very similar to the structure determined previously for the K(9eG)8+ complexes. The stability of K2(9eG)122+ toward unimolecular dissociation and its binding energy were examined using energy-resolved sustained off-resonance collision induced dissociation (SORI-CID) and blackbody infrared radiative dissociation (BIRD) kinetics experiments. SORI-CID experiments showed that the self-assembled K2(9eG)122+ complex undergoes charge separation forming K(9eG)8+ and K(9eG)4+ compared to K(9eG)8+ which loses neutral 9eG. More interestingly, K2(9eG)122+ is more stable toward unimolecular dissociation activated by SORI-CID than the K(9eG)8+ complex. Temperature dependent BIRD kinetics for K2(9eG)122+ were consistent with energy-resolved SORI-CID results showing K2(9eG)122+ to have an activation energy of 225 ± 15 kJ mol-1, approximately 50 kJ mol-1 greater than that determined for K(9eG)8+. The extra stability of K2(9eG)122+ is apparently not thermodynamic stability, but most likely due to an energy barrier for dissociation.