Patterns in foliar nitrogen (N) stable isotope ratios (&delta;¹⁵N) have been shown to reveal trends in terrestrial N cycles, including the identification of ecosystems where N deficiencies limit forest ecosystem productivity. However, there is a gap in our understanding of within-species variation and species-level response to environmental gradients or forest management. Our objective is to examine the relationship between site index, foliar %N, foliar &delta;¹⁵N and spectral reflectance for managed Douglas-fir (<i>Pseudotsuga menziesii</i>) and loblolly pine (<i>Pinus taeda</i>) plantations across their geographic ranges in the Pacific Northwest and the southeastern United States, respectively. Foliage was measured at 28 sites for reflectance using a handheld spectroradiometer, and further analyzed for &delta;¹⁵N and N concentration. Unlike the prior work for grasslands and shrubland species, our results show that foliar &delta;¹⁵N and foliar %N are not well correlated for these tree species. However, multiple linear regression models suggest a strong predictive ability of spectroscopy data to quantify foliar &delta;¹⁵N, with some models explaining more than 65% of the variance in the &delta;¹⁵N. Additionally, moderate to strong explanations of variance were found between site index and foliar &delta;¹⁵N (<i>R</i>² = 0.49) and reflectance and site index (<i>R</i>² = 0.84) in the Douglas-fir data set. The development of relationships between foliar spectral reflectance, &delta;¹⁵N and measures of site productivity provides the first step toward mapping canopy &delta;¹⁵N for these managed forests with remote sensing.Published version