Radioactive decay of potassium (K), thorium (Th), and uranium (U) power the Earth's engine, with variations in ²³²Th/²³⁸U recording planetary differentiation, atmospheric oxidation, and biologically mediated processes. We report several thousand ²³²Th/²³⁸U (κ) and time-integrated Pb isotopic (κ_Pb) values and assess their ratios for the Earth, core, and silicate Earth. Complementary bulk silicate Earth domains (i.e., continental crust ^CCκ_Pb = 3.94 ^+0.20_-0.11 and modern mantle ^MMκ_Pb = 3.87 ^+0.15_-0.07, respectively) tightly bracket the solar system initial ^SSκ_Pb = 3.890 ± 0.015. These findings reveal the bulk silicate Earth’s ^BSEκ_Pb is 3.90 ^+0.13_-0.07 (or Th/U = 3.77 for the mass ratio), which resolves a long-standing debate regarding the Earth’s Th/U value. Experimental studies find marked differences in the partitioning of U and Th during core formation. We performed a Monte Carlo simulation to calculate the κ_Pb of the BSE and bulk Earth for a range of U concentrations in the core (from 0 to 10 ng/g). Comparison of our results with ^SSκ_Pb constrains the available U and Th budget in the core. Negligible Th/U fractionation accompanied accretion, core formation, and crust - mantle differentiation, and trivial amounts of these elements (0.07 ppb by weight, equivalent to 0.014 TW of radiogenic power) were added to the core and do not power the geodynamo.