Equations of Motion for an Economy: Capital Deepening, Technology, and Firm Survival

Abstract

We derive equations of motion for capital deepening in a competitive economy directly from accounting identities, without assuming a production function. A profit imperative η* (w/ + 1/τ)/(1-fp) sets the minimum viable capital productivity, where η = Y/K [yr-1] is capital productivity, = K/L is capital per worker, w is the wage rate, τ is the capital lifetime, and fp is the production tax share. Four coupled relaxation equations govern , η, the frontier productivity η new of new investment, and the labor share q w/y, with the sandwich constraint η* ≤ η new ≤ η maintained as an exact invariant. The frontier equation separates two physically distinct channels: a structural cheapening channel (μ, always active, drives η new downward) and a productivity channel (φ, historically zero). Calibration against BEA 2-digit NAICS sector data (1998--2023) confirms φ = 0 for all identifiable sectors over 25 years; the 75-year postwar record extends this finding across four capital lifetimes. A step φ = 0.01\,yr-1 -- a 1\%/yr improvement in new-capital productivity, modest but historically unprecedented -- nearly doubles the aggregate growth rate within one capital lifetime, a falsifiable prediction with a precise observable signature: upward-curving η(t) in BEA sector data. Firms near the zero-profit threshold have a cash martingale, predicting establishment exit rate t-1/2; convolved with the Zipf firm-size distribution~WP, this yields firm exit rate t-1/2\! t with apparent exponent b = 0.295 0.03, confirmed against BDS data with no free parameters.