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The efficient and modular diversification of molecular scaffolds, particularly for the synthesis of diverse molecular libraries, remains a significant challenge in drug optimization campaigns. The late-stage introduction of alkyl fragments is especially desirable due to the high sp³-character and structural versatility of these motifs. Given their prevalence in molecular frameworks, C(sp²)−H bonds serve as attractive targets for diversification, though this process often requires difficult pre-functionalization or lengthy de novo syntheses. Traditionally, direct alkylations of arenes are achieved by employing Friedel–Crafts reaction conditions using strong Brønsted or Lewis acids. However, these methods suffer from poor functional group tolerance and low selectivity, limiting their broad implementation in late-stage functionalization and drug optimization campaigns. Herein, we report the application of a novel strategy for the selective coupling of differently hybridized radical species, which we term dynamic orbital selection. This mechanistic paradigm overcomes common limitations of Friedel-Crafts alkylations via the in situ formation of two distinct radical species, which are subsequently differentiated by a copper-based catalyst based on their respective binding properties. As a result, we demonstrate herein a general and highly modular reaction for the direct alkylation of native arene C−H bonds using abundant and benign alcohols and carboxylic acids as the alkylating agents. Ultimately, this solution overcomes the synthetic challenges associated with the introduction of complex alkyl scaffolds into highly sophisticated drug scaffolds in a late-stage fashion, thereby granting access to vast new chemical space. Based on the generality of the underlying coupling mechanism, dynamic orbital selection is expected to be a broadly applicable coupling platform for further challenging transformations involving two distinct radical species.