The statistical mechanics of innovation diffusion

This paper proposes a novel agent-based model for new-product diffusion, grounded in the kinetic theory of statistical mechanics. The model describes a population of utility-driven agents whose adoption decisions emerge from belief dynamics shaped by peer influence, advertising, and stochastic factors. By adapting the Boltzmann equation, a closed-form expression for the adoption curve is derived as an emergent property of decentralized, compromise-based interactions. Unlike aggregate models such as the Generalized Bass Model or the Bass Logit Diffusion Model, the proposed Kinetic Innovation Diffusion (KID) model links micro-level behavioral rules to macro-level adoption dynamics without relying on top-down assumptions. Empirical validation on benchmark products—including color televisions, air conditioners, clothes dryers, and freezers—demonstrates that the KID model outperforms existing methods in both fit and early-stage forecast accuracy. Thanks to its tractable structure, the model enables estimation of key strategic quantities from minimal data, making it a valuable tool for pre-launch planning and early diffusion monitoring. Its flexibility also supports extensions to incorporate heterogeneity, abandonment, or strategic firm behavior—offering a unified, analytically grounded framework for innovation diffusion.