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Abstract: Reconstructing the building blocks that made Earth and the Moon is critical to constrain their formation and compositional evolution to the present. Neodymium (Nd) isotopes identify these building blocks by fingerprinting nucleosynthetic components. In addition, the <sup>146</sup>Sm–<sup>142</sup>Nd and <sup>147</sup>Sm–<sup>143</sup>Nd decay systems, with half-lives of 103 million years and 108 billion years, respectively, track potential differences in their samarium (Sm)/Nd ratios. The difference in Earth’s present-day <sup>142</sup>Nd/<sup>144</sup>Nd ratio compared with chondrites (Burkhardt et al., Nature, 2016; Bouvier et al., Nature, 2016), and in particular enstatite chondrites, is interpreted as nucleosynthetic isotope variation in the protoplanetary disk. This necessitates that chondrite parent bodies have the same Sm/Nd ratio as Earth’s precursor materials (Bouvier et al., Nature, 2016). Here we show that Earth and the Moon instead had a Sm/Nd ratio approximately 2.4 ± 0.5 per cent higher than the average for chondrites and that the initial <sup>142</sup>Nd/<sup>144</sup>Nd ratio of Earth’s precursor materials is more similar to that of enstatite chondrites than previously proposed (Burkhardt et al., Nature, 2016; Bouvier et al., Nature, 2016). The difference in the Sm/Nd ratio between Earth and chondrites probably reflects the mineralogical distribution owing to mixing processes within the inner protoplanetary disk. This observation simplifies lunar differentiation to a single stage from formation to solidification of a lunar magma ocean (McLeod, et al., Earth Planet. Sci. Lett., 2014). This also indicates that no Sm/Nd fractionation occurred between the materials that made Earth and the Moon in the Moon-forming giant impact.