Dynamic Spatial Treatment Effects as Continuous Functionals: Theory and Evidence from Healthcare Access
Abstract
I develop a continuous functional framework for spatial treatment effects grounded in Navier-Stokes partial differential equations. Rather than discrete treatment parameters, the framework characterizes treatment intensity as continuous functions τ(x, t) over space-time, enabling rigorous analysis of boundary evolution, spatial gradients, and cumulative exposure. Empirical validation using 32,520 U.S. ZIP codes demonstrates exponential spatial decay for healthcare access ( = 0.002837 per km, R2 = 0.0129) with detectable boundaries at 37.1 km. The framework successfully diagnoses when scope conditions hold: positive decay parameters validate diffusion assumptions near hospitals, while negative parameters correctly signal urban confounding effects. Heterogeneity analysis reveals 2-13 × stronger distance effects for elderly populations and substantial education gradients. Model selection strongly favors logarithmic decay over exponential ( AIC > 10,000), representing a middle ground between exponential and power-law decay. Applications span environmental economics, banking, and healthcare policy. The continuous functional framework provides predictive capability (d*(t) = * t), parameter sensitivity (∂ d*/∂ ), and diagnostic tests unavailable in traditional difference-in-differences approaches.
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