Carbon-13 NMR lanthanide induced shifts and T1 studies of the conformation of friedelin

## Abstract Carbon‐13 NMR chemical shifts (CDCl~3~ and C~6~D~6~ solvents) and relaxation times (__T__~1~) were determined for carbons in a series of allenic esters [RR~1~CCCHCO~2~ Et; (1) R = R~1~ = H; (2) R = H, R~1~ = CH~3~; (3) R = H, R~1~ = CH~3~CH~2~; (4) R = R~1~ = CH~3~; (5) R = CH~3~, R~1

## Abstract 2‐Azetidinones which carry a proton each on C‐3 and C‐4 often pose a problem in the correct assignment of the resonances due to these protons; titanium tetrachloride has been shown to be an effective and reliable n.m.r. shift reagent to differentiate between these two protons on the bas

The ' ' C chemical shifts of triterpenoidal olefins and epoxides related to lanosterol are described and discussed. The epoxide function located in the central part of the tetracyclic steroidal skeleton allows the evaluation of epoxidation-induced shifts (EIS) for several carbons. The most character

The 13C chemical shifts of cis-and trans-benzylidenepropylamine and substituted benzylideneanilines were analysed after additons of Eu(fod),. The cisltrans ratio increases as the amount of lanthanide shift reagent increased. The cis isomers showed large lanthanide-induced shifts, whereas the trans i

## Abstract A new incremental scheme for the calculation of the ^13^C NMR chemical shifts in polysubstituted benzenes with homogeneous substituents was derived and applied to spectral prediction for C~6~X~n~H~6−n~ where XCH~3~, C~2~H~5~, __i__‐C~3~H~7~, CF~3~, F, Cl, Br, COOH. Owing to the use of

## Abstract Characteristic ^13C^ chemical shift ranges and substituent shifts of heterocyclic ring carbon atoms have been identified for a number of 1‐aryl‐3‐phenyl‐2‐thioxo‐4‐imidazolidinones. ^13^CNMR spectra may be used to detect slow internal rotation about the aryl CN‐1 bond in compounds with