NMR chemical shift substituent effects: 2-α-monosubstituted N,N-diethylacetamides

## Carbon -13 NMR chemical shifts of a series of a-monosubstituted N,N-diethylacetamides [YCH,C(O)NEt, , Y = Me, C1, Br, I, OMe, SMe, and NMe,] are reported. The a-methylene and carbonyl carbon chemical shifts are correlated with the Pauling electronegativities (E,) and Charton's localized electri

NMR chemical shifts for some a-heterosubstituted acetones were recorded. The carbonyl carbon shieldings are discussed in the light of the substituent electronic effects and were also empirically estimated by Tanaka et d ? s equation. An approximate linear relationship was observed between the I3C an

## Abstract ^13^C NMR chemical shifts for some 3‐heterosubstituted 2‐methylpropenes are reported. The α‐methylene chemical shifts show excellent linear correlations with the corresponding data for some substituted carbonyl compounds (propanones, methyl acetates and __N__,__N__‐diethylacetamides). T

## Abstract ^13^C NMR chemical shift assignments of 47 __N__‐mono‐ and __N,N__‐disubstituted 3‐aminopyrroles with hydrogen or methyl in the 5‐position are reported. Substituents in the 2‐position are electron withdrawing such as alkoxycarbonyl, cyano or acyl in most cases and those in the 4‐positio

## Abstract The ^15^N NMR spectra of three __N__‐alkyl‐δ‐carbomethoxyvalerothiohydroxamic acids (**2**) and six synthesized __N__‐isopropylbenzothiohydroxamic acids (**3**) were measured and compared with appropriate spectra of structurally similar hydroxylamines (**1**), benzohydroxamic acids (**4

## Abstract A principal component analysis is applied to α‐monosubstituted ethyl acetates (YCH~2~CO~2~Et), where the observed chemical shifts for the α‐carbon atom, the carbonyl carbon, and the α‐hydrogen atoms are correlated with theoretically derived molecular properties, i.e. the partial charges