Hole wave functions and transport with deazaadenines replacing adenines in DNA.

Transport of a hole along the base stack of DNA is relatively facile for a series of adenines (As) paired with thymines (Ts) or for a series of guanines (Gs) paired with cytosines (Cs). However, the speed at which a hole was found to travel was much too small to make useful semiconductor-type devices. Quite recently it was found that replacing one of the electronegative nitrogens (N3 or N7) with a carbon and a hydrogen, thus turning A into deazaadenine, increased the hole speed in what was A/T by a factor 30. To study the effect of the substitution we have carried out simulations for the wave function of a hole on an A/T oligomer with As modified by replacing N3 or N7, or both, with C–H’s. The simulations were carried out using QM/MM and the code CP2K. We find, for either N, or both, replaced, the wave function of the hole behaves similarly to that of a hole on A/T in being delocalized immediately after hole insertion for up to ∼20 fs, and then becoming localized on one of the modified As. The time for lo...