Two self-complementary dinucleotide analogues T(Si)A and A(Si)T with a nonionic diisopropylsilyl-modified backbone were synthesized, and their association in a nonaqueous aprotic environment was studied by NMR spectroscopy. Using a CDClF2/CDF3 solvent mixture, measurements at temperatures as low as 113 K allowed the observation and structural characterization of individual complexes in the slow exchange regime. The A(Si)T analogue associates to exclusively form a dinucleotide antiparallel duplex with regular Watson-Crick base pairing, but both A and T nucleosides exhibit a predominant C3'-endo sugar pucker reminiscent of an A-type conformation. In contrast to A(Si)T, the T(Si)A dinucleotide is found to exhibit significant variability and flexibility. Thus, different secondary structures with weaker hydrogen bonds for all T(Si)A structures are observed at low temperatures. Although a B-like Watson-Crick antiparallel dinucleotide duplex with a preferred C2'-endo sugar pucker largely predominates at temperatures above 153 K, two additional species, namely a dinucleotide Hoogsteen duplex with a syn glycosidic torsion angle of the adenosine nucleoside and a presumably intramolecularly folded structure, are increasingly populated upon further cooling. By adding typical DNA intercalators like anthracene or benz[c]acridine derivatives to the A(Si)T dinucleotide duplex in the aprotic solvent environment, no binding of the polycyclic aromatic molecules can be detected even at lower temperatures. Obviously, van der Waals and stacking interactions are insufficient to compensate for the other unfavorable contributions to the overall free energy of binding, and only in the presence of additional hydrophobic effects in an aqueous environment does binding occur.